Messaging system

ABSTRACT

A messaging system is provided for communicating a message between a first communications unit having a first messaging entity and a second communications unit having a second messaging entity, each messaging entity having a messaging call control means for establishing a messaging communications link with the other messaging entity; and a messaging means for, once the messaging communications link has been established, exchanging messaging information with the said other messaging entity. Also a method is provided for communicating a message between a first communications unit and a second communications unit, the first communications unit having an application layer, a messaging entity and a network layer.

BACKGROUND OF THE INVENTION

This invention relates to a messaging system, in particular a messaging system for use in the DECT (Digital European Cordless Telecommunications) system and other communications systems such as WCPE (Wireless Customer Premises Equipment) and PHS (Personal Handyphone System). The system may be used to provide a multipurpose messaging service that can be used for access to alternate data/messaging services with a common air interface structure accomplished with a general protocol layer defined on the top of the DECT protocol layers.

One implementation of a DECT system will now be described.

The Digital European Cordless Telecommunications (DECT) is a standard provided for cordless communications for both voice and data traffic. Reference may be had to the ETSI documents defining the system, which are incorporated herein by reference. A DECT system includes at least one portable part (PP) and at least one fixed part (FP). The PP contains all elements between the user and the air interface whereas the FP contains all elements between a local network and air interface. Thus no fixed infrastructure has been defined. The connection to the networks is made through interworking unit (IWU), functions of which are defined in the DECT profiles.

The DECT protocol layer structure is illustrated in the FIG. 1. The following descriptions of the layers are based on the common interface standard ETS 300 175-1 to 9. Radio Equipment and Systems (RES); Digital European Cordless Telecommunications (DECT) Common interface Part 1-9. European Telecommunications Standards Institute 1992 thus the features described here form a library of services for use by different profiles. DECT provides on the physical layer, in the frequency band of 1880-1900 MHz, 10 carriers each of which are carrying 24 TDMA slots. The slots can be used for either bi-directional (12 slots for both directions) or unidirectional traffic (maximum of 23 slots for one direction). The gross bit rate is 1152 kbit/s. A timeslot is divided into control/signalling (4.8 kbit/s net rate) and traffic fields (32 kbit/s net rate).

The medium access layer (MAC) can provide broadcast, connectionless and connection oriented service. The connection oriented service can be non-protected or protected. The protected service provides a possibility for modulo 2 retransmisson.

The data link control layer is divided into C- (signalling and low rate user traffic) and U-planes (user traffic). The U-plane can provide the following services for the upper layer application: LU1 transparent unprotected data (for voice), LU2 frame relay (data), LU3 frame switching (LU2 with LAP protocol for data), LU4 forward error correction (data), LU5 and LU6 rate adaptation for V.110 traffic. In addition LU7 is defined in the DECT/ISDN interworking profile to provide services for ISDN traffic.

The network layer on the C-plane contains the following services: Call Control (CC) used for call establishment and maintenance, mobility management (MM), call independent supplementary service (CISS) used for supplementary services, connection oriented message service (COMS) is an acknowledgment service used for transportation of limited amount of user data and Connectionless message service (CLMS) used for broadcast or point to point connectionless traffic. Call related supplementary services (CRSS) are related to a CC call and it provides a specific keypad protocol for the service management. The U-plane does not have a network layer.

BRIEF SUMMARY OF THE INVENTION

According to a first aspect of the present invention there is provided a messaging system for communicating a message between a first communications unit having a first messaging entity and a second communications unit having a second messaging entity, each messaging entity comprising: a messaging call control means for establishing a messaging communications link with the other messaging entity; and a messaging means for, once the messaging communications link has been established, exchanging messaging information with the said other messaging entity.

Preferably, the messaging entity constitutes a virtual layer between the application layer and the network layer of the communication protocol.

The messaging information suitably includes header data and user data associated with the message. The header data and the user data suitably include data defining a message sequence number of the message. The header data and the user data are preferably carried by different communications links. Most preferably one link operates through a C-plane and the other link operates through a U-plane of a communication protocol.

The messaging system suitably operates according to the DECT, WCPE or PHS protocols. One of the communications units may be a portable part and the other is a fixed part. Alternatively, one of the units may be an intermediate server unit. One of the communications units may be provided with an interworking unit for performing protocol conversion.

According to the present invention from a second aspect there is provided a messaging method for communicating a message between a first communications unit and a second communications unit, the first communications unit having an application layer, a messaging entity and a network layer, the method comprising the steps of: transmitting a signal from the application layer to the network layer as a means of establishing a call; exchanging messaging information between the application layer and the network layer by way of the messaging entity to communicate the message; and transmitting a signal from the application layer to the network layer as a means of disconnecting the call.

According to the present invention from a third aspect there is provided a messaging method for communicating a message between a first communications unit and a second communications unit, the first communications unit having an application layer, a messaging entity and a network layer, the method comprising the steps of: transmitting a signal from the messaging entity to the network layer as a means of establishing a call; exchanging messaging information between the application layer and the network layer by way of the messaging entity to communicate the message; and transmitting a signal from the messaging entity to the network layer as a means of disconnecting the call.

In the messaging system/method commands can preferably be sent between messaging entities of each communications unit. The commands preferably include MMS SEND, MMS RETREIVE, MMS-RETREIVE-RPY, MMS COMMAND, MMS-COMMAND-RPY and MMS STATUS.

A messaging entity can preferably request a reply from the other messaging entity or an end entity. The said header data is preferably conveyed in one or more DECT/WCPE/WLL call control information elements and most preferably in one CC message.

The messaging system/method preferably includes any or all aspects of the up/downgrading, the service negotiation and the interworking procedures and the <<BASIC-SERVICE>> element described below.

The present invention suitably relates to a system for, for instance, providing teleservices for FAX and short message (such as GSM SMS) transfer. This may suitably allow for GSM interworking and also, generally, may extend the capabilities of DECT systems. In the future the demand for data messaging may also expand to other teleservices/data services (such as Internet based messaging/file transfer) and the present invention may preferably provide for this too. Employing a preferred embodiment of the invention a DECT system may expand from a cordless telephone system into a multipurpose information system with a wide variety of information services. At the same time it may offer also basic voice traffic and hence widen the possibilities for DECT service providers and manufacturers.

The present invention suitably provides a messaging service for a DECT system which can provide a wide variety of network services with a single new protocol layer compared to prior art DECT systems. In this way a simple and cheap portable terminal with wide variety of messaging/data services may suitably be provided for users. The protocol preferably contains a general set of minimum functionality for all alternate services, because the services contain such a wide variety of different options that it may conceivably be difficult to accomplish all functions of different services at the same time while maintaining a low level of complexity of a protocol.

The new protocol layer will be referred to as a multipurpose messaging service (MMS). The MMS protocol may preferably provide for general interworking to multiple information services such as T.611 Fax, GSM SMS, CCITT X.400 and internet HTTP.

The protocol may preferably be usable by both short messaging and fax/file services. The principal difference between these type of services is in the transmission capability: the short messaging preferably uses only the control channel (C-plane) for MMS signalling and user data transfer whereas the fax/file service preferably uses the traffic channel (U-plane) for user data and control channel (C-plane) for MMS signalling. This type of structure can suitably provide a flexible service. That is, a U-plane bearer service (C.2 data profile) can suitably be upgraded into fax/file transfer-teleservice by adding the MMS protocol on it. Also short messaging (E profile) can suitably be upgraded to a fax service by adding the U-plane service to the short messaging. Downgrading is preferably also possible. These procedures can suitably be done during already established connection as illustrated in FIG. 2. This procedure can be utilized for instance by sending the user a short message indicating that a fax is arriving. The user can, if he is capable to receive the fax, upgrade his short message connection into a fax capable high speed service to receive the fax.

Since the prior art DECT air interface typically supports only a limited service negotiation capability, the present invention preferably also provides for a new flexible service negotiation, suitably by adding new elements to some DECT messages. In this way the service negotiation may suitably be more flexible and some interworking unit/network service parameters may suitably be negotiated/changed even during call establishment. Also a new coding of the DECT IWU selection (<<iwu-attributes >>) element may preferably be used to provide more general coding to IWU service selection. This may help to overcome the problem that prior art DECT coding is only ISDN oriented and does not fit well into general data service selection. The new coding is preferably backwards compatible with the old coding.

Aspects of the present invention may help to provide the following advantages:

allowing a wide set of services to be accessed in a standardized simple way;

providing relatively simple terminal applications, so the terminals can be simple and cheap;

providing an up/down grading procedures allowing a user friendly flexible service system to be implemented;

allowing expansion of the DECT systems and terminals for future data services;

minimizing the changes required in the DECT protocol layers

keeping close to the GAP DECT general voice profile, reducing the changes required in standard DECT terminals

Processing aspects of the present invention may suitably be provided by appropriate software operating under the control of a processor in a fixed or portable part.

BRIEF DESCRIPTION OF THE DRAWINGS

The present invention will now be described by way of example only, with reference to the accompanying schematic drawings, in which:

FIG. 1 shows DECT layers and services;

FIG. 2 shows the upgrading/downgrading procedures;

FIG. 3 shows MMS definitions;

FIG. 4 shows MMS API relations;

FIG. 5 shows MMS interaction half API and non-API cases;

FIG. 6 shows MMS interaction full API case;

FIG. 7 shows MMS internal structure;

FIG. 8 shows modeling;

FIG. 9 shows the complete MMS layer structure;

FIG. 10 shows the full-API MMS model;

FIG. 11 shows the half-API MMS model;

FIG. 12 shows the non-API MMS model;

FIG. 13 shows the MMS general functional model;

FIG. 14 shows the horizontal functions related to MMS messaging;

FIG. 15 shows MMS implementation for E and F profiles;

FIG. 16 shows the MMS action relations;

FIG. 17 shows MMS send action options;

FIG. 18 shows MMS retrieve action options;

FIG. 19 shows MMS Command action options;

FIG. 20 show MMS Status action options;

FIG. 21 shows MMS SETUP and CONNECT actions;

FIG. 22 shows MMS RELEASE action;

FIG. 23 shows MMS implementation for E and F profiles;

FIG. 24 shows the upgrading/downgrading procedures;

FIG. 25 shows outgoing MMS call;

FIG. 26 shows incoming MMS call;

FIG. 27 shows the BASIC-SERVICE information element;

FIG. 28 shows the CALL-ATTRIBUTES information element;

FIG. 29 shows the IWU-ATTRIBUTES information element;

FIG. 30 shows the FACILITY information element;

FIG. 31 shows the CALLED-PARTY-NUMBER information element;

FIG. 32 shows the ALPHANUMERIC information element;

FIG. 33 shows the SERVICE-CHANGE-INFO information element;

FIG. 34 shows the FEATURE-ACTIVATE information element;

FIG. 35 shows the FEATURE-INDICATE information element;

FIG. 36 shows the IWU-TO-IWU information element;

FIG. 37 shows the CC-INFOrmation message;

FIG. 38 shows MMS and GSM SMS interworking;

FIG. 39 shows MMS and GSM Facsimile 3 interworking;

FIG. 40 shows MMS and PSTN Facsimile 3 interworking;

FIG. 41 shows MMS and Internet HTTP interworking;

FIG. 42 shows MMS and Internet FTP interworking;

FIG. 43 shows MMS and X.400 interworking;

FIG. 44 shows DECT MMS and GSM SMS transparent interworking;

FIG. 45 shows extended exchange attributes negotiation in the case of outgoing call; and

FIG. 46 shows extended exchange attributes negotiation in the case of incoming call.

DETAILED DESCRIPTION OF THE INVENTION

The MMS definitions and the MMS functional model will first be defined and concepts relating to the MMS, its architecture, basic functionality and the relationship of the MMS to the DECT protocol layer model and to the outside networks will be clarified.

The horizontal MMS model defined below specifies the position of the MMS and the MMS entities in relation to the outside networks and in DECT physical and logical entities (FPs, PPs and IWUs). The architecture section below defines the MMS virtual layer internal structure. The functions section below defines the functionality of the MMS virtual layer. Full-API, half-API and non-API models are also clarified below.

The vertical MMS model defined below specifies the position of the MMS to the DECT layer structure: to the DECT network layer (NWK) and to the application/Interworking Unit (IWU).

The following bullets give a general view of the MMS functions, its advantages and its properties.

MMS is a generic set of commands and information elements for file/messaging service.

MMS provides a generic file handling/messaging services over the DECT air interface by utilizing the DECT transportation mechanism in the best way possible at the same time offering a general set of functions to the applications using its services.

MMS provides a compact subset of functions to information servers with the advantage that a single terminal with MMS support can use a wide variety of information and messaging services with minimum amount of application layer complexity. If a complete set of services is needed an escape sequence has to be used or some other means such as transparent protocol transportation mechanism are needed.

MMS is in fact a DECT messaging service with wide selection of data types. It is very much like GSM SMS with wider variety of data types and operations without the length limitation of the messages. Thus MMS provides GSM SMS SM-TP layer services as a subset of its functions.

MMS is not a real protocol layer in the terms of OSI model but it is a virtual layer which utilizes the services of the DECT Call Control entity. It could be regarded as a supplementary service type of service that provides signalling/control and application specific information related to the teleservices provided by the DECT data profiles. MMS messages are part of the DECT Call Control messages and are accessed through the CC primitives.

For the MMS and data profiles utilization an Application Programming Interface (API) can be used to provide an application independent interface. This interface provides a standard set of a primitives for MMS messaging. However, even though the application see the MMS as protocol layer when using the API access points the MMS is only utilizing the CC entity functions with some added features.

MMS itself is a stateless virtual protocol which defines a set of framing rules and information elements each containing optional and mandatory information fields.

MMS can be regarded as a non-existent protocol layer. That is, it does not have to exist in real DECT protocol layer structure. However, it is treated in this context as a real (virtual) protocol layer for clarifying the concepts, functions and vertical interactions in the protocol structure.

The MMS horizontal definitions (i.e. the relations of the messaging service to the outside networks as well as the different DECT MMS and outside (IWU) network entities) will now be defined. FIG. 3 illustrates some of the MMS definitions.

Portable MMS Entity: Portable MMS Entity is the PP.

Fixed MMS Entity: Fixed MMS Entity is the FP with Interworking Unit (IWU).

MMS entity: Portable MMS Entity or Fixed MMS Entity, an entity with MMS messaging capabilities

MMS action: MMS actions take place between MMS entities. The actions provide means for message and file transfer or retrieval between these MMS entities. Also a set of controlling actions are available for the remote transactions focused into a MMS message/file stored/handled by the Message Control Entity. The Message Control Entity may send status information data as a response to a control action or to a specific request set by other MMS actions.

Message Control Entity: The Message Control Entity is a server that is responsible for the controlling of the message sent by a MMS entity or the End Entity. It can be either the intermediate server or fixed MMS entity. The Portable MMS entity can control the messages in the Message Control Entity i.e. request the status, cancel the message forwarding etc. Also the portable MMS entity may be a Message Control Entity. In this case the Fixed MMS Entity or the intermediate server can control the message in the Portable MMS Entity. After the Message control entity has finished its transaction (forwarding the message) the message cannot be controlled anymore. In this case only status information regarding the message can be requested from or sent by the Message Control Entity.

Intermediate server: An optional intermediate server can be in the messaging network. This intermediate server is on the other side of the Fixed MMS Entity IWU i.e. in the interworked network. The protocol between the Fixed MMS Entity and the intermediate server may be selected by the MMS (primary IWU conversion) as well as the protocol between the intermediate and the End Entity (secondary IWU conversion). The selection of these protocols can be left to the Message Control Entity and/or to the Fixed MMS Entity. The intermediate server could be a GSM Short message service center (SC) or a Fax server in LAN environment. With MMS the message/file processing taking place in the intermediate server can be controlled. In this case the intermediate server is the Message Control Entity. If no intermediate server address is defined then the Fixed MMS Entity is the Message Control Entity.

End entity: The End Entity is the final object of the message transfer. It does not necessarily understand MMS messaging i.e. the Fixed MMS Entity (primary IWU conversion) or the intermediate server (secondary IWU conversion) may do protocol conversion according to the requests set in the MMS messages. The End Entity can also be another MMS entity, for instance, the Fixed MMS Entity can forward a MMS message to another the Portable MMS Entity. In this case the Fixed MMS Entity is Message Control Entity.

MMS addressing: MMS protocol provides addressing for the intermediate server and End Entity. The intermediate server address is provided during the MMS call establishment to define the intermediate server as a Message Control Entity. If no address has been defined the fixed MMS entity is the Message Control Entity. The End Entity address is sent in MMS actions. If no End Entity address is present then the message is processed by default by the Message Control Entity.

Primary IWU conversion: The protocol conversion done in the Fixed MMS Entity according to the request of the MMS action or spontaneously according to interworking requirements.

Secondary IWU conversion: The protocol conversion done in the intermediate server according to the request of the MMS action that is converted to a action in the Fixed MMS entity or spontaneously according to interworking requirements.

The functionality of the MMS will now be described. In general the MMS functions as a stateless protocol. The full API protocol model defines the internal structure of the MMS API and the MMS virtual layer when the call control interactions are done by the MMS part itself directly according the rules defined in the interworking definitions. The half and non-API protocol models define how the MMS API or non-API primitives are used to control the MMS call and send MMS messages according to the definitions done in the service interworking definitions (see FIG. 4).

In half-API and non-API models the only task of the MMS is to packetize the information received from the application. The MMS standard frame format contains MMS specific information. After framing the MMS requests the network layer to transport the frames over the air interface. MMS layer may provides primitives for call control and MMS transportation to the application layer and the entity uses NWK primitives. In this case it is a half API interface (i.e. MMS does only framing) and in fact the call control primitives it offers to the application are network layer primitives. The other option, the non-API, is to define MMS as a set of information elements and framing rules. In this case the application will use directly the network layer primitives for call establishment, control and release and there are no MMS primitives. In this case MMS is only an addition of the CC or COMS entity (i.e. not more than a new set of information elements). The procedures relating to call control behavior are done in the interworking definitions. Thus the application becomes more complex.

FIG. 5 shows the following instructions: 1. Call establishment; 2. Message/file transfer (with MMS framing); 3. Link suspend/resume (optional); 4. Response received; and 5. Call disconnect. The features of the models are listed below.

Half-API Model

API primitives available to the upper layer

MMS is a set of framing and messaging rules

stateless

the application controls the call control through API primitives

Non-API Model

DECT NWK primitives used by the upper layer

MMS is a set of framing and messaging rules, the application fulfills these rules for its own purposes

stateless

the application controls the call control directly through the NWK primitives

Some potential advantages and disadvantages of this protocol model are:

MMS is a part of CC or COMS entity thus no additional protocol layer structure has to be defined into DECT standard

the MMS definition is easy i.e. it is only a set of framing rules and information elements

the call establishment procedures can be built into the application or interworking annex. This is important since the procedures vary from application to application.

In the full-API model the MMS is a protocol layer with only few primitives such as MN-MMS-SEND.Req, MN-MMS-FETCH.Req or MN-MMS-SEND-RPY.Ind. The call establishment is solely the matter of MMS layer (i.e. it establishes a call and sends the data by using Network layer primitives). The rules for MMS functionality are different in different cases of interworking service: i.e. the requirements of FTP are different to GSM SMS. The MMS information general descriptions are done in the general definitions and the required behavior of the MMS with network layer is defined in the interworking annexes to different services. Thus the complexity is moved from the application to MMS. In this case MMS is a full Application Programming Interface (API) that provides a standard access point for the applications.

FIG. 6 shows the following interactions: 1. Call establishment; 2. Message/file transfer; 3. Link suspend/resume (optional); 4. Response received; and 5. Call disconnect. The features of the model are listed below.

Full-API Model

limited set of API primitives available to the upper layer

MMS is a set of framing and messaging rules

stateless or states

the MMS controls the call control using NWK primitives

Some potential advantages and disadvantages of this protocol model are:

A question raises whether MMS is part of DECT network layer or the interworking unit or a new protocol layer. The latter may imply a change in the structure of DECT

The application remain simple, however, it is possible that the MMS behavior varies from application to application. Thus in each service interworking annex the MMS call control would have to be defined. This lowers the level of flexibility.

The MMS virtual layer internal architecture will now be defined in general terms.

The MMS entity is divided into two separate parts: the call control entity (C-MMS) and the messaging entity (M-MMS). The structure is illustrated in FIG. 7. The C-MMS and M-MMS detailed functionality is service/application dependent and is described in the specific interworking descriptions.

The MMS messaging part provides means to the upper layer (application/IWU) to send and received MMS specific messages with MMS specific information between two horizontal MMS entities. The M-MMS part can only function if either the C-MMS part has established a connection between the horizontal entities according to the request of the M-MMS or the upper layer entity. M-MMS may provide a set of primitives to the upper layer or not. It contains MMS messaging framing rules and those rules may be either utilized by defining a set of primitives or the application itself may fulfill these framing/message contents rules when utilizing the MMS services. That is, in the former case DECT provides a standard MMS application programming interface (full or half MMS-API) to the upper application. In this case M-MMS-SAP exists. In the latter case DECT provides standard rules for MMS messaging to the upper layer applications. In this case DECT CC primitives are directly used and no M-MMS-SAP exists (non-API).

The M-MMS may control optionally the C-MMS part of the MMS entity by using as the access point the M/C-MMS-SAP point which is a service access point defined in between MMS virtual layer parts. The functionality of the M-MMS towards the C-MMS entity may be defined in the service/application interworking definitions. This is the full API model.

The M-MMS part can be itself divided into two parts: User data and User control data parts.

User data part provides the functionality to convey the pure data the user (application) wants to transmit i.e. a fax image data, the short message text etc.

User control data part provides the functionality to convey the additional control data that is combined into the MMS message such as control information to the server, time stamp information, recipient address, response request.

The MMS Call Control Part establishes a connection between two horizontal MMS entities according the request of either the upper layer entity (application or IWU) or the M-MMS part. It forwards the call control requests to the lower layers. The C-MMS-SAP may exist on the upper interface. C-MMS-SAP defines the required information for call establishment. However, it exists only in the case the MMS-API has been defined into the MMS. Another option is that the upper layer (application/IWU) fulfills the connection control requirements defined in the DECT interworking profiles. This is the half API or non-API model.

The optional M/C-MMS-SAP resides between M-MMS and C-MMS parts. Thus it cannot be accessed by the application and it is not a part of the MMS-API. It is a C-MMS service access point and provides part of the C-MMS-SAP primitives directly to the M-MMS part. The M-MMS part usage of the M/C-MMS-SAP is defined in the, interworking definition which is specific to a service to be interworked. The upper layer application cannot control completely the call is the case of the M/C-MMS-SAP usage. That is, the M-MMS is in this case responsible of the call establishment and release. The link suspension and release may be requested by the application. This is the full API model.

The MMS vertical relations (i.e. how it interacts its functionality with the upper and lower protocol layers) will now be defined.

The vertical model defines a (full and half) MMS-API, and a non-API interfaces to the application/interworking. The API provides a standard set of primitives to the upper layers. The non-API defines the rules/primitives of the CC entity for a standard set of MMS actions.

In order to provide full functionality the interworking of the protocol has to be defined to both directions: up to the application/interworking unit and down to the DECT layers. The following chapter defines the interworking definitions and the chapter following that defines the functionality of the DECT upper layers with MMS (see FIG. 8).

MMS-API layer is a completely optional feature and it is intended to provide a standard application interface to the application and interworking units (IWU) exploiting the MMS services and facilities. It provides two services access points (SAPs) to the upper layer. These access points are defined below. The MMS-API and MMS internal structure has been illustrated in FIG. 9.

The M-MMS-SAP resides on the MMS-API, thus it is applicable for the upper layer application. M-MMS-SAP is intended for requesting MMS message transportation or reception. If the feature of providing control between the MMS parts (the M/C-MMS-SAP) is present and the interworking description defines its functionality, the MMS action initiated by primitives through the M-MMS-SAP takes care of the call control functions. That is, no C-MMS-SAP call establishment primitives have to be used for call establishment. This is the full API protocol layer model and it is illustrated in FIG. 10.

In the case of half-API model the MMS connection control has to be done by the upper layer application directly utilizing the C-MMS-SAP primitives. The half-API model is illustrated in FIG. 11.

The C-MMS-SAP resides on the MMS-API, thus it is accessible for the upper layer application. The C-MMS-SAP primitives are used for MMS call control directly by the upper layer application. In the case of M/C-MMS-SAP usage the set of the primitives is limited and the main control of the call is done by the M-MMS part as defined in an appropriate service interworking definition.

The non-API interface defines how the DECT Call Control primitives can be utilized by the application/interworking unit directly in order to facilitate MMS actions. Thus no standard MMS-API interface is provided. This type of action takes place on the lower layer of the MMS-API plane. The non-API model has been illustrated in FIG. 12.

The relations of MMS towards the DECT Network Layer is as the non-API model. Thus the interface between the MMS virtual protocol layer is defined as a set of rules how the DECT NWK and DECT U-plane DLC primitives are used for MMS call control and MMS messaging. This is applicable for all half, full and non-API models.

M-MMS uses DECT Call Control messaging and information elements and DECT U-plane DLC layer for the MMS messages transfer. Thus M-MMS uses the Call Control and U-plane services.

C-MMS uses the normal DECT Call Control procedures for call establishment, suspension, resumption and release. Thus C-MMS is the same as the DECT Call control entity.

The MMS relations according to the horizontal model (i.e. how the MMS protocol relates through the vertical model to Portable MMS entity, Fixed MMS entity with Interworking Unit, Intermediate server and outside network) will now be defined. The general model containing elements from both models is illustrated in FIG. 13. In the figure the Interworking function in fixed MMS entity is defined optionally, since the message control entity can be also in the Fixed MMS entity. The functions in the figure are in the End Entity dependent on the accessed service.

FIG. 15 illustrates a general MMS horizontal functional model. It should be noted that the procedures in the figure are not MMS actions but basic functions required for reaching the interworking services. Those procedures that have been drawn with dotted lines are optional i.e. these are not required by all services. A procedure is part of a MMS action, either C-MMS or M-MMS, thus a MMS action consists of MMS procedures defined here. Each procedure is defined next with a reference to the FIG. 14.

Procedure 1. Establish a radio link. This is a C-MMS procedure. The purpose is to establish a DECT radio link with MMS capabilities.

Procedure 2. Select IWU. This is part of a C-MMS procedure. The purpose is to select the Interworking Unit in the Fixed MMS entity in order to facilitate the required message mappings and access to the requested service.

Procedure 3. Select a server. This an optional C-MMS procedure. In some cases the intermediate server is accessed through a network the Fixed MMS entity provides access. This procedure is used to defined the server with identification (for instance, internet address, GSM SMS SC number etc.). If the fixed entity provides the service then this procedure is not needed.

Procedure 4. Connect to server. This is an optional C-MMS procedure. The connection is established through the network into the server.

Procedure 5. Login to server. This is a M-MMS procedure. In some cases a login procedure by user or application is required to reach access to the service provided by the server. For instance, in the FTP services case.

Procedure 6. Select 2nd IWU. This is a M-MMS procedure. The purpose is to select the Interworking Unit in the Intermediate server in order to facilitate the required message mappings or to reach required service.

Procedure 7. Send a message. This is a M-MMS procedure. This procedure is the actual message that is sent to the server for processing. Depending on the service either the server replies itself or forwards the message and then replies.

Procedure 8. Receive server response. This is a M-MMS procedure. The server has sent a response to the previously sent message.

Procedure 9. Receive end entity response. This is a M-MMS procedure. The server may send a response received from the end entity to the MMS portable entity.

Procedure 10. Disconnect from server. This is a M-MMS procedure. This is a procedure used to disconnect the connection to a server residing in a network (for instance, in internet).

Procedure 11. Disconnect from Fixed entity. This is a C-MMS procedure. This is a procedure used to disconnect the air interface.

A set of consecutive procedures can be combined into a single C- or M-MMS procedure. For example, procedures 1 (establish a radio link) and 2 (select 1s IWU) can be done with CC-SETUP message.

The MMS is utilized by the DECT data profiles E (Low rate messaging service) and F (Multimedia Messaging Service). It should be noted that even though the MMS protocol and F profile have the same name they are not the same. The F profile will only contain the MMS protocol definition but it will contain also definitions how the DECT U-plane is used for the data transmission (see FIG. 15).

The Low Rate Messaging Service (LRMS, E data profile) will use the MMS for short message transfer. In this case the User data and user control data is conveyed through the M-MMS part. The C-MMS part is used for call control.

The Multimedia messaging service (F data profile) will use the MMS for high speed data transfer. The User data is conveyed through the U-plane using LU3-SAP and the user control data is conveyed using M-MMS part. C-MMS part will take care of the Call control.

The MMS consists of different actions related to message/file handling. Not all actions are required in order to interwork to a specific interworking services i.e. a minimum subset of the following actions and information elements of the messages can be selected in order to facilitate interworking. However there is no limitation to implement all of them in addition to the minimum required set. The actions are defined as application layer information. The action information contents is divided into M-MMS and C-MMS actions/primitives by the content of the actions (see FIG. 16).

The MMS SEND action is meant for data (message) transfer (sending) in both directions i.e. PP to FP and FP to PP. The reply is an optional feature and it can be requested by a specific field in the MMS-SEND message (see FIG. 17).

The following table shows the MMS-SEND message contents.

Field in MMS-SEND Status Comment USER CONTROL PART Action type M Distinguishes MMS actions Reply request M Is a reply requested for the action MMS sequence M A sequence number to distinguish number MMS messages NOTE 1. Service type M Defines the interworking service/network Service subtype O Defines the subtype of the service Message M Defines messaging specific transmission type information Data content type M The upper layer (application) protocol of the interworking protocol (subtype of the service) Time Stamp O When message was sent Recipient address M/O The address of the recipient Sender address M/O The address of the sender Segmented info O Contains segmentation information USER DATA PART Character type M The data type in the user data field coding Character set coding M Language coding O Language of the message User data length M The length of user data field. NOTE 1. User data M The user data defined in Data type field NOTE. The MMS sequence number can be duplicated to both parts user control and user data parts when the message content is splitted between two data flow paths. This numbering is used to combine the data again in the IWU. The length also.

The following table shows the MMS-SEND-RPY message contents

Field in MMS-SEND- RPY Status Comment USER CONTROL PART Action type M Distinguishes MMS actions MMS sequence M A sequence number to distinguish number MMS messages Action result M Result of the action Control data length O Indicates if escape data is present Control data O Escape field for application specific commands

The MMS-RETRIEVE action is meant for data (message) retrieval for both directions i.e. PP to FP and FP to PP. The reply containing the information retrieved is carried in MMS-RETRIEVE-RPY message (see FIG. 18).

The following table shows the MMS-RETRIEVE message contents

Field in MMS- RETIREVE Status Comment USER CONTROL PART Action type M Distinguishes MMS actions Reply request M Is a reply requested for the action In this case the reply is always requested MMS sequence M A sequence number to distinguish number MMS messages Service type O Defines the interworking service, used for message selection Intermediate O The address of the optional server address intermediate server MMS sequence M The message number for number requested message Data content type O The user data type Command type O The operation to be done to the message in the service after successful retrieval

The following table shows the MMS-RETRIEVE-RPY message contents

Field in MMS- RETRIEVE-RPY Status Comment USER CONTROL PART Action type M Distinguishes MMS actions MMS sequence M A sequence number to distinguish number MMS messages (this action) Service type M Defines the interworking service used Network address M The address of the recipient or sender (address type) Message M Defines messaging specific transmission type information Data content type M The upper layer (application) protocol of the interworking protocol Action result M Result of the action MMS sequence M The message number for requested number message Time Stamp O When message was sent Segmented info O Contains segmentation information USER DATA PART Character type M The data type in the user data field coding Character set M coding Language coding O Language of the message User data length M The length of user data field. NOTE 1. User data M The user data defined in Data type field

MMS COMMAND action is meant for server control information transfer. With this functionality information stored/processed in the remote end can be controlled remotely (for instance, a status information can be requested or message scheduled for sending can be canceled). The control reply (MMS-COMMAND-RPY) is an optional reply requested with a specific field in the MMS-COMMAND message (see FIG. 19).

The following table shows the MMS-COMMAND message contents

Field in MMS- COMMAND Status Comment USER CONTROL PART Action type M Distinguishes MMS actions Reply request M Is a reply requested for the action MMS sequence M A sequence number to distinguish number MMS messages Service type O Defines the interworking service used Time Stamp M When message was sent (in status information) Intermediate O The address of the optional server address intermediate server Data content type M The upper layer (application) protocol of the interworking protocol Command object M The command object number (MMS sequence number) Command type M The operation Escape M Indicates the presence of an application commands/inform specific command in user field ation present Control data M Indicates if escape data is present length Control data O Escape field for application specific commands

The following table shows the MMS-COMMAND-RPY message contents

Field in MMS- COMMAND-RPY Status Comment USER CONTROL PART Action type M Distinguishes MMS actions MMS sequence M A sequence number to distinguish number MMS messages Time Stamp O When message was sent Command object M The command object number (MMS sequence number) Command type O The operation Action result M Result of the action Control data M Indicates if escape data is present length Control data O Escape field for application specific commands

MMS STATUS action is meant for messaging control information transfer. With this functionality a status information can sent independently of the pervious requests. The status reply (MMS-STATUS-RPY) is an optional reply requested with a specific field in the MMS-STATUS message. This message never contains user information. It can be used for informing waiting messages/files in server. In this case the message may contain detailed information about the message (see FIG. 20).

The following table shows the MMS-STATUS message contents

Field in MMS- STATUS Status Comment USER CONTROL PART Action type M Distinguishes MMS actions Reply request M Is a reply requested for the action MMS sequence M A sequence number to distinguish number MMS messages Time Stamp M When message was sent (in status information) Information type M The operation Action result M/O Result of the action Command object O The number of the message the action is referring to (MMS sequence number) Sender address O The address of the sender Service type O Defines the interworking service/network Service subtype O Defines the subtype of the service Data content type O The upper layer (application) protocol of the interworking protocol (subtype of the service) Message length O The length of the message waiting in server

The following table shows the MMS-STATUS-RPY message contents

Field in MMS- STATUS-RPY Status Comment USER CONTROL PART Action type M Distinguishes MMS actions MMS sequence M A sequence number to distinguish number MMS messages Action result M Result of the action

The following table shows the Information elements in M-MMS actions

Element Values Length Comment Action MMS-SEND 4 bits Distinguishes MMS type MMS-SEND-RPY actions MMS-RECEIVE MMS-RECEIVE-RPY MMS-CONTROL MMS-CONTROL-RPY MMS-STATUS MMS-STATUS-RPY Reply No reply requested 2 bits Is a reply request From MMS entity requested for the From End entity action From MMS and End entity MMS Value 0-127 with 7-14 A sequence sequence extension bits number to number 0-16384 distinguish MMS messages Network Number type: The address of the address As in ETS300 175-5 recipient or Address 7.7.7. senderThe type of Type: Alphanumeric (with address used in DECT alphabets) address fields. Numbering plan: Values coded as As in ETS 300 175-5 in DECT <<Called 7.7.7. party number>> IP address IE with some IP server name (URI) additions X.400 address LAN address Service Not specified 7 bits The interworking type Any method service Address based IWU This is the service selection type used through A message handling the message facility control entity Physical (secondary IWU Voice telephone selection in most Telex of the cases). Teletex Facsimile group 3 Facsimile group 4 Videotex (T.100/T.101) ERMES National paging UCI (ETS 300 133-3) GSM SMS DECT MMS DECT LRMS IA5 terminal X.400 message handling FTP HTTP Gopher News News/NNTP Telnet Wide area info server Host specific file names Prospero Service None 4 bits These values are subtype Standard related to the Telex: Service type field Standard i.e. not all listed Via teletex conversion values are possible Teletex: with all service type Standard options. The service Oper. doc. options related to Monit doc the value of the Ctrl doc. Service type is TFT of Doc. tr. Mode defined. (TFT; TFT of Binary File Tr. Telematic File TFT of Edifact Transfer). in PSPDN in CSPDN in analog PSTN in digital ISDN Facsimile group 3: Standard TFT of Basic tr.Mode TFT of Doc. tr. Mode TFT of Binary File Tr. TFT of Edifact Facsimile group 4: Standard Oper. doc. Monit doc Ctrl doc. TFT of Doc. tr. Mode TFT of Binary File Tr. TFT of Edifact Message Unspecified 3 bits This field indicates transmission Encapsulated the structure of the type Multipart MMS message, i.e. Body in U-plane multipart means Header in C-plane sementation and Normal body in U-plane means F profile functionality. Message Undefined 7 bits This field specifies content type Specified by the the content of the service type message i.e. the Local type format of the Simple formattable message content. document Basic text: IA 5 text (T.50) Telex Teletex (T.61) Videotex (T.100/T.101) image TIFF image GIF image JPEG image Fax G 4 class 1 Fax G 3 (T.4/T.30) Audio AVI audio Multipart: mixed Multipart: parallel Multipart: alternative Multipart: digest Encapsulated: RFC 822 or MIME Encapsulated: GSM SMS Encapsulated: X.400 Octet stream application Postscript application MPEG video Character Others 3 bits The data type in type coding Standard 8 bit the user data field characters Coded as in Standard 4 bit coding <<Alphanumeric Standard 7 bit >>IE in DECT characters with some Binary additions Compressed Encrypted Character 8 bit characters: 3 bits When language set coding DECT standard 8 bit coding is used the 8 bit ASCII length of the field US-ASCII is extended with 7 ISO 8859 bits. 8 bit EBCDIC 7 bit characters: 7 bit ERMES 7 bit standard ASCII 7 bit ASCII (IA5/T.50) Others: ASN.1. BER.1 User specific National variations of IRA Compressed: ZIP V.42 bis Encrypted: GSM encryption DECT encryption Language German 7 bits The language of coding English the message Italian French Spanish Dutch Swedish Danish Portuguese Finnish Norwegian Greek Turkish Reserved for European languages Language unspecified Time Stamp Date, Time, Timezone 7 When message octets was sent User data Tells the amount of 1-4 The length of user length octets in the user octets data field data field. User data Variable The user data defined by message content and data coding type fields Action General values: 7 bits Result of the result Successful action Unsuccessful Command successful Command unsuccessful Successful transactions: Message sent to end entity Message received by server Message received by end entity Message replaced by the server Temporary Error: No memory available Congestion End entity busy No response from end entity Quality of service not available Error in end entity Permanent Error: invalid address Incompatible file type Invalid network(End User not accessible) Service rejected End entity not available Primary IWU conversion failed Command Values as in MMS 7 or The command object coding 14 object number 0 reserved for bits (MMS sequence connection control number) If this field is omitted or it contains value 0 the command is related to the connection Command Message related: 7 bits The operation type Delete Replace Cancel Memory available Status Enquiry Cancel status enquiry Connection related: Login Logout Information Status report 7 bits type Message/file waiting in server Escape yes 1 bit Indicates the commands no presence of an present application specific command in user field Control Variable Indicates if escape data length data is present Control Variable Escape field for data application specific commands Segmented 4 Contains info octets segmentation information

The following actions use the DECT Call Control functionality directly for the MMS call controlling. The following clauses are describe generally their functionality. The procedures referred here are defined above. The actions are described here for consistency but basically they are DECT CC functionality and the their true functionality is described below.

The following actions can be accessed through the MMS-API in the full- and half-API cases or similar functionality can be reached through the DECT MNCC-SAP in the non-API case. The required information content of these C-MMS service actions is defined here and the mapping between respective DECT and MMS functions set out below.

The purpose of the MMS-SETUP action is to initiate a MMS connection through the air interface. It contains the procedures 1, 2, and 3. As a result of receiving these procedures the fixed MMS entity may also proceed with procedure 4. This functionality is done by using DECT CC-SETUP functionality.

The result of the MMS-SETUP action is accepted by sending a MMS-CONNECT message. The receiving MMS entity accepts the MMS call establishment and informs the intitating entity. The action is conducted by using DECT CC-CONNECT messages.

In unsuccessful cases of the connection establishment the release of the connection is a matter of the lower layer entities. The connection release is done in unsuccessful cases either by MMS-RELEASE of by MMS-RELEASE-COM (see FIG. 21).

The following table shows the MMS-SETUP message contents

Field in MMS- SETUP Status Comment Iwu-attributes M Defines the profile requirements (the interworking unit) Called-Party- O Defines the server number. This Number number is optional. Calling-Party- O Informs the server number. This Number number is optional.

The MMS-CONNECT message contains no MMS specific information.

A normal release between MMS is done by the MMS-RELEASE action procedure. This action contains the procedure 11 of FIG. 14. It may also contain procedure 10. The response is MMS-RELEASE-COM.

Abnormal situations are done by MMS-RELEASE-COM message.

The detailed functionality of these procedures are in the layers below MMS (see FIG. 22).

The following table shows the MMS-RELEASE message contents

Field in MMS- RELEASE Status Comment Release reason O Defines the reason for the release

The following table shows the MMS-RELEASE-COM message contents

Field in MMS- RELEASE-COM Status Comment Release reason O Defines the reason for the release

The information element coding in C-MMS actions is done as defined below.

The defined MMS protocol information elements could be implemented to the DECT layers as illustrated in FIG. 23. A group of new information elements have to be defined but also a group of already existing DECT elements could be utilized by adding some new codings. Additions of the old and new information elements into DECT Call Control or COMS and U-plane messages has to be done.

Also the primitives related to the MMS-API should be defined. In the case MMS-API is used the layer does mapping between MMS-API primitives and DECT NWK and U-plane primitives.

The mapping of the M-MMS and C-MMS information elements into DECT messages will now be defined. The reference column of the tables refer to the clause which defines the information element. By reading the IE the field mapping is straigthforward. Detailed information on how the used DECT messages are coded is also presented.

The following table shows the M-MMS messages

Sta- tus Map Item in Sta- No MMS MSG DECT MSG GAP Ref. tus Note 1 MMS-SEND CC-INFO M 7.3.2.1 M 2 MMS-SEND CC-INFO/U- I 7.3.2.2 M 1. plane LAPU frame 3 MMS-SEND-RPY CC-INFO M 7.3.2.3 M 4 MMS-RETRIEVE CC-INFO M 7.3.2.4 M 6 MMS-RETRIEVE- CC-INFO M 7.3.2.5 M RPY 5 MMS-RETRIEVE- CC-INFO/U- I 7.3.2.6 M 1. RPY plane LAPU frame 7 MMS- CC-INFO M 7.3.2.7 M COMMAND 8 MMS- CC-INFO M 7.3.2.8 M COMMAND-RPY 9 MMS-STATUS CC-INFO M 7.3.2.9 M 10 MMS-STATUS- CC-INFO M 7.3.2.10 M RPY NOTE. This mapping take place only when the MMS (F-data profile) is using the MMS.

The following table shows the MMS-SEND-CC-INFO

Message coding Message coding Item MMS DECT NWK GAP Map No MMS-SEND CC-INFO status Ref. status NOTE 1 Action type Facility or MMS I 8.2.4; 8.2.6 M 2. 2 Reply request Facility or MMS I 8.2.4; 8.2.6 M 2. 3 Recipient Called party I 8.2.5 M address number 4 Sender address Calling party I 8.2.5 M number 5 Service type Facility or MMS I 8.2.4; 8.2.6 M 2. 6 Service subtype Facility or MMS I 8.2.4; 8.2.6 M 2. 7 Message Facility or MMS I 8.2.4; 8.2.6 M 2. transmission type 8 Data content Facility or MMS I 8.2.4; 8.2.6 M 2. type 9 Time Stamp Time/data I 8.2.7 M 3. 10 MMS sequence Facility or MMS I 8.2.4; 8.2.6 M 2. number 11 Character type Alphanumeric I 8.2.8 M 1. coding 12 Character set Alphanumeric I 8.2.8 M 1. coding 13 Language coding Alphanumeric 1 8.2.8 O 1. 14 User data length Alphanumeric I 8.2.8 M 1. 15 User data Alphanumeric I 8.2.8 M 1. 16. Segmented info Segmented info I ETS 300 M 1. 175-5, 5. 7.7.37 18. Content type IWU-TO-IWU I 8.2.12 4. 19. User data IWU-TO-IWU I 8.2.12 4. NOTE 1. This mapping take place only when the LRMS (E-data profile) is using the MMS. NOTE 2. Either a new coding of Facility element is used or a new information element MMS is defined and used (See below). NOTE 3. A new information element is defined for this purpose below. NOTE 4. This mapping takes place if the <Message transmission type> field of the MMS message contains value “Encapsulated”. NOTE 5. This mapping takes place if the <Message transmission type> field of the MMS message contains value “Multipart” or the segmentation may function independently of the MMS messaging as DECT NWK internal matter.

The following table shows the MMS-SEND-CC-INFO/U-plane LAPU frame

Message coding Message coding Item MMS DECT NWK GAP Map No MMS-SEND CC-INFO status Ref. status NOTE 1 Action type Facility or MMS I 8.2.4; 8.2.6 M 2. 2 Reply request Facility or MMS I 8.2.4; 8.2.6 M 2. 3 Recipient Called party I 8.2.5 M address number 4 Sender address Calling party I 8.2.5 M number 5 Service type Facility or MMS I 8.2.4; 8.2.6 M 2. 6 Service subtype Facility or MMS I 8.2.4; 8.2.6 M 2. 7 Message Facility or MMS I 8.2.4; 8.2.6 M 2. transmission type 8 Data content Facility or MMS I 8.2.4; 8.2.6 M 2. type LAPU frame 4. 9 Time Stamp Time/data I 8.2.7 M 3. 10 MMS sequence Facility or MMS I 8.2.4; 8.2.6 M 2. number LAPU frame 4. 11 Character type LAPU frame I 7.3.4. M 1. coding 12 Character set LAPU frame I 7.3.4. M 1. coding 13 Language coding LAPU frame I 7.3.4. O 1. 14 User data length LAPU frame I 7.3.4. M 1. 15 User data LAPU frame I 7.3.4. M 1. NOTE 1. This mapping take place only when the MMS (F-data profile) is using the MMS. Then the <Message transmission type> field of the MMS message contains value “Body in U-plane” NOTE 2. Either a new coding of Facility element is used or a new information element MMS is defined and used.(See below). NOTE 3. A new information element is defined for this purpose in below. NOTE 4. The element is carried in both LAPU frame and CC-INFO message.

The following table shows the MMS-SEND-RPY-CC-INFO

Message coding Message coding Item MMS MMS- DECT NWK GAP Map No SEND-RPY CC-INFO status Ref. status NOTE 1 Action type Facility or MMS I 8.2.4; 8.2.6 M 2. 2 MMS sequence Facility or MMS I 8.2.4; 8.2.6 M 2. number 3 Action result Facility or MMS I 8.2.4; 8.2.6 M 2. NOTE 2. Either a new coding of Facility element is used or a new information element MMS is defined and used.(See chapter 8).

The following table shows the MMS-RETRIEVE-CC-INFO

Message coding Message coding Item MMS MMS- DECT NWK GAP Map No RETRIEVE CC-INFO status Ref. status NOTE 1 8.2.4; 8.2.6 Facility or MMS I 8.2.4; 8.2.6 M 2. 2 MMS sequence Facility or MMS I 8.2.4; 8.2.6 M 2. number 3 Service type Facility or MMS I 8.2.4; 8.2.6 M 2. 4 intermediate Called party I 8.2.5 M server address number 5 MMS sequence Facility or MMS I 8.2.4; 8.2.6 M 2. number 6 Data object type Facility or MMS I 8.2.4; 8.2.6 M 2. 7 Command type Facility or MMS I 8.2.4; 8.2.6 M 2.

Message coding MMS Message coding Item MMS- DECT NWK GAP Map No RETRIEVE-RPY CC-INFO status Ref. status NOTE 1 Action type Facility or MMS I 8.2.4; 8.2.6 M 2. 2 MMS sequence Facility or MMS I 8.2.4; 8.2.6 M 2. number 3 Service type Facitity or MMS I 8.2.4; 8.2.6 M 2. 4 Network Called party I 8.2.4; 8.2.6 M address (with number address type) 5 Data content Facility or MMS I 8.2.4; 8.2.6 M 2. type 6 Action result Facility or MMS I 8.2.4; 8.2.6 M 2. 7 MMS sequence Facility or MMS I 8.2.4; 8.2.6 M 2. number 8 Time Stamp Time/Date I 8.2.7 M 3. 9 Character type Alphanumeric I 8.2.8 coding 10 Character set Alphanumeric I 8.2.8. M 1. coding 11 Language Alphanumeric I 8.2.8. coding 12 User data length Alphanumeric I 8.2.8. M 1. 13 User data Alphanumeric I 8.2.8. M 1. 16. Segmented info Segmented info I ETS 300 M 1. 175-5 5. 7.7.37. NOTE 1. This mapping take place only when the LRMS (E-data profile) is using the MMS. NOTE 2. Either a new coding of Facility element is used or a new information element MMS is defined and used.(See below). NOTE 5. This mapping takes place if the <Message transmission type> field of the MMS message contains value “Multipart” or the segmentation may function independently of the MMS messaging as DECT NWK internal matter.

The following table shows the MMS-RETRIEVE-RPY-CC-INFO/LAPU frame

Message coding MMS Message coding Item MMS- DECT NWK GAP Map No RETRIEVE-RPY CC-INFO status Ref. status NOTE 1 Action type Facility or MMS I 8.2.4; 8.2.6 M 2. 2 MMS sequence Facility or MMS I 8.2.4; 8.2.6 M 2. number 3 Service type Facility or MMS I 8.2.4; 8.2.6 M 2. 4 Network Called party I 8.2.5 M address (with number address type) 5 Data content Facility or MMS I 8.2.4; 8.2.6 M 2. type LAPU frame 4. 6 Action result Facility or MMS I 8.2.4; 8.2.6 M 2. 7 MMS sequence Facility or MMS I 8.2.4; 8.2.6 M 2. number LAPU frame 4. 8 Time Stamp Time/Date I 8.2.7 M 3. 9 Character type LAPU frame 7.3.4 coding 10 Character set LAPU frame 7.3.4 M 1. coding 11 Language LAPU frame 7.3.4 coding 12 User data length LAPU frame 7.3.4 M 1. 13 User data LAPU frame 7.3.4 M 1. NOTE 1. This mapping take place only when the MMS (F-data profile) is using the MMS. NOTE 2. Either a new coding of Facility element is used or a new information element MMS is defined and used.(See below). NOTE 3. A new information element is defined for this purpose below. NOTE 4. The element is carried in both LAPU frame and CC-INFO message.

The following table shows the MMS-COMMAND-CC-INFO

Message coding MMS Message coding Item MMS- DECT NWK GAP Map No COMMAND CC-INFO status Ref. status NOTE 1 Action type Facility or MMS I 8.2.4; 8.2.6 M 2. 2 Reply request Facility or MMS I 8.2.4; 8.2.6 M 2. 3 MMS sequence Facility or MMS I 8.2.4; 8.2.6 M 2. number 4 Service type Facility or MMS I 8.2.4; 8.2.6 M 2. 5 Time Stamp Time/Date I 8.2.7 M 6 Intermediate Called party I 8.2.5 M server address number 7 Data content Facility or MMS I 8.2.4; 8.2.6 M 2. type 8 Command Facility or MMS I 8.2.4; 8.2.6 M 2. object 9 Command type Facility or MMS I 8.2.4; 8.2.6 M 2. 10 Escape Facility or MMS 8.2.4; 8.2.6 M 2. commands present 11 Control data IWU-TO-IWU I 8.2.12 M length 12 Control data IWU-TO-IWU I 8.2.12 M NOTE 2. Either a new coding of Facility element is used or a new information element MMS is defined and used.(See below).

The following table shows the MMS-COMMAND-RPY-CC-INFO

Message coding MMS MMS- Message coding Item COMMAND- DECT NWK GAP Map No RPY CC-INFO status Ref. status NOTE 1 Action type Facility or MMS I 8.2.4; 8.2.6 M 2. 2 MMS sequence Facility or MMS I 8.2.4; 8.2.6 M 2. number 3 Time Stamp Time/Date I 8.2.7 M 4 Command Facility or MMS I 8.2.4; 8.2.6 M 2. object 5 Command type Facility or MMS I 8.2.4; 8.2.6 M 2. 6 Action result Facility or MMS I 8.2.4; 8.2.6 M 2. 9 Control data IWU-TO-IWU I 8.2.12 M length 10 Control data IWU-TO-IWU I 8.2.12 M NOTE 2. Either a new coding of Facility element is used or a new information element MMS is defined and used.(See below).

The following table shows the MMS-STATUS-CC-INFO

Message coding Message coding Item MMS DECT NWK GAP Map No MMS-STATUS CC-INFO status Ref. status NOTE 1 Action type Facility or MMS I 8.2.4; 8.2.6 M 2. 2 Reply request Facility or MMS I 8.2.4; 8.2.6 M 2. 3 MMS sequence Facility or MMS I 8.2.4; 8.2.6 M 2. number 5 Time Stamp Time/Date I 8.2.7 M 6 Information type Facility or MMS I 8.2.4; 8.2.6 M 2. 7 Action result Facility or MMS I 8.2.4; 8.2.6 M 2. 8 Command Facility or MMS I 8.2.4; 8.2.6 M 2. object 9 Control data IWU-TO-IWU 8.2.12 M length 10 Control data IWU-TO-IWU 8.2.12 M 11 Sender address Calling party I 8.2.5 M number 12 Service type Facility or MMS I 8.2.4; 8.2.6 M 2. 13 Service subtype Facility or MMS I 8.2.4; 8.2.6 M 2. 14 Data content Facility or MMS 8.2.4; 8.2.6 M 2. type 15 Time Stamp Time/Date I 8.2.7 M 16 User data length Facility or MMS I 8.2.4; 8.2.6 M 2. NOTE 2. Either a new coding of Facility element is used or a new information element MMS is defined and used.(See below).

The following table shows the MMS-STATUS-RPY-CC-INFO

Message coding Message coding Item MMS MMS- DECT NWK GAP Map No STATUS-RPY CC-INFO status Ref. status NOTE 1 Action type Facility or MMS I 8.2.4; 8.2.6 M 2. 2 MMS sequence Facility or MMS I 8.2.4; 8.2.6 M 2. number 3 Action result Facility or MMS I 8.2.4; 8.2.6 M 2. NOTE 2. Either a new coding of Facility element is used or a new information element MMS is defined and used.(See below).

The following table shows the C-MMS messages

TABLE x List of mapped C-MMS messages Item Status Map No MMS MSG DECT MSG in GAP Ref. Status 1 MMS-SETUP CC-SETUP M 7.3.3.1 M 2 MMS-CONNECT CC-CONNECT M 7.3.3.3 M 3 MMS-RELEASE CC-RELEASE M 7.3.3.2 M 4 MMS-RELEASE- CC-RELEASE- M 7.3.3.2 M COM COM

The following table shows the MMS-SETUP-CC-SETUP

Message Message coding coding GAP Map Item MMS DECT NWK sta- sta- No MMS-SETUP CC-SETUP tus Ref. tus NOTE 1 Iwu-attributes Iwu-attributes I 8.2.2 M 2 called party called party I M number number 3 calling party calling party I M number number

The following table shows the MMS-CONNECT-CC-CONNECT

Message Message Item coding coding GAP No MMS DECT NWK status Ref. Map status NOTE MMS- CC- CONNECT CONNECT

The following table shows the MMS-RELEASE-CC-RELEASE

Message Message GAP Item coding coding sta- Map No MMS DECT NWK tus Ref. status NOTE MMS- CC-RELEASE RELEASE Release reason Release reason

The following table shows the MMS-RELEASE-COM-CC-RELEASE-COM

Message Message GAP Item coding coding sta- Map No MMS DECT NWK tus Ref. status NOTE MMS- CC-RELEASE- RELEASE- COM COM Release reason Release reason

The added information element required in addition to GAP will now be defined. As defined elsewhere in this document the MMS virtual protocol can be regarded as service that supports the DECT data teleservices such as short messaging and facsimile. Thus the idea here is to provide the MMS User control coding and MMS messaging coding in the way DECT supplementary services are provided. This means that the MMS can be intitated during the call establishment but also a low bearer service connection can be upgraded into a full MMS connection. It should be noted that in the case of E-profile (LRMS) the MMS cannot be a supplementary service for voice call since the voice call has its own transaction identifier and the MMS service is cannot provide any additional information to this service. This is why in this document the expression Supplementary Service is avoided when referred to MMS. Thus MMS is an additional service that can be used to upgrade a bearer service into a full teleservice and this can be done even during the bearer service connection. This is possible in the case of F-data profile in a way that the C.2 profile which is the bearer service under the F can be upgraded into F profile by initiating the MMS connection during the call. In the case of LRMS a completely new CC instance has to be intitated without U-plane. The E profile can be also upgraded into F profile by adding a C.2 U-plane connection under the MMS protocol. Thus the following rules apply (see FIG. 24).

If C.2 is on and the MMS is activated to the same Call Control transaction the connection is upgraded into F.2 profile. Also other way around.

If E.2 is on and the C.2 U-plane is activated to the same Call Control transaction the connection is upgraded to F.2 connection. Also other way around.

The C.2 and E.2 can exist at the same time in a same terminal with separate transactions as well as F.2 and E.2.

For upgrading the C.2 to F.2 profile uses the <<Feature activate>> element. This can be done only in the direction PP to FP. The FP can indicate MMS activation with <<Feature indicate>> field.

For upgrading the E.2 to F.2 profile the CC-SERVICE-CHANGE message has to be used.

<<Facilty>> or new <<MMS protocol>> element in {CC-INFO} message is used for MMS message transfer in general.

When E and F profile call is established the systems initiate the MMS by default.

Since prior art DECT air interfaces support only a limited service negotiation capability, also a new service negotiation is also now proposed by adding the <<iwu-attributes>> element to the {CC-INFO} message. In this way the service negotiation is more flexible and some interworking unit/network service parameters can be negotiatied/changes even during the call establishment. Also a new coding of the <<iwu-attributes>> element is defined below to provide more general coding to IWU service selection. This was done due to fact that current coding of the <<iwu-attributes>> element is only ISDN oriented and does not fit well into general data service selection. The new coding is backwards compatible with the old coding.

The call establishment has been illustrated in FIG. 24 in actions 1 and 2. It should be noted that additional signalling may take place between the {CC-SETUP} and {CC-CONNECT}. The {CC-SETUP} message will contain the following information in addition to the GAP requirements.

status Field within Standard Information in the information values within Normative element GAP element the field/IE action/comment <<Portable M Coded as in GAP identity>> <<Fixed M Coded as in GAP Identity>> <<Basic M service>> <Call class> 1 1 1 0 “Messaging call setup” Note 1. <Basic 1 1 1 1 “Other” The service> coding is defined by <<iwu attributes>> and <<call attributes>> <<Iwu- I Note 1. attributes>> <Coding 0 1 “Profile specific standard> coding” Note 1. <Profile ID> 0 0 0 1 1 “ E profile ” or 0 0 1 0 0 “ F profile” Note 1. <HLC ID> 1 0 Octet identifier Note 1. <HLC coding 0 0 0 0 1 “User protocol ID indicator> present” Note 1. <User protocol 1 1 0 0 1 “DECT LRMS/ ID> MMS (MMSP)” Note 1. Rest of the codings are depending on the requested service. Note 1. <<call I attributes>> <Coding 0 0 DECT standard> Network layer 0 1 1 0 0 “DECT LRMS attributes service profile (E data profile” or 0 1 1 0 1 “DECT MMS service profile (F data profile)” Note 1. Rest of the codings are depending on the requested service. Note 1. <<connection I attributes>> All codings are situation and profile dependent <<Number of 0 0 0 0 0 “No-U-plane” in bearer E profile case coding>> <<Called I party number>> <Number 0 1 1 “Server number” type> Note 1. <Numbering Value depends on plan the interworked identification> network <<Calling I party number>> <Number 0 1 1 “Network specific type> number” <Numbering Value depends on plan the interworked identification> network NOTE. Contains new coding(s). See below.

{CC-CONNECT} message content is as it is defined in the GAP DRAFT prETS 300 444.Version 2.02. Radio Equipment and Systems (RES); Digital European Cordless Telecommunications (DECT): Generic Access Profile (GAP). European Telecommunications Standards Institute. May 1994.138 pages, i.e. all fields are optional.

The Low Rate Messaging Service (LRMS, the E-data profile) messaging uses {CC-INFO} messages to convey the MMS messages. In this case the CC-INFO contains the MMS user data information, the MMS user data control information as well as the MMS messaging information.

The following table shows the {CC-INFO} message content for this:

status Field within Standard Information in the information values within Normative element GAP element the field/IE action/comment <<Multi M Not used with keypad>> MMS <<Facility>> I Either this element or <<MMS>> element <Service 1 0 0 1 0 “Discriminator discriminator> for MMS service applications” <Components> Contains the MMS control information <<Calling- I Defines the MMS Party- message sender Number>> number. Note 1. <Number 0 1 1 “Network specific type> number” <Numbering Value depends on plan the interworked identification> network <<Called- I Defines the MMS Party- message recipient Number>> number <Number 0 1 1 “Network specific type> number” <Numbering Value depends on plan the interworked identification> network <<Called- I May contain Party- additional Subaddress>> information related to the recipient <Subaddress Value depends on type> the interworked network <Odd/Even> Value depends on the interworked network <<Time/ I Date information. date>> Note 1. <<MMS>> I Either this of <<Facility>> element contains the MMS control information. Note 1. <<Segmented I Contains info>> information if the <<Alphanumeric >>element has been segmented. Note 1. <<Alpha- I Note 1. numeric>> <Character type> <Odd/Even> <Character set coding> <List of Contains the characters> message information <<IWU-TO- I May contain IWU>> upper layer messages or escape commands <Protocol ID> Contains coding regarding the message content NOTE 1. New coding(s)/element. See below.

The Multimedia Messaging Service (MMS, the F-data profile) messaging uses CC-INFO messages to convey the MMS messages. In this case the CC-INFO contains the MMS user data control information as well as the MMS messaging information. The user data information is conveyed through the U-plane LAPU connection. The MMS message in CC-INFO transmits the control information related to the connection.

The following table shows the {CC-INFO} message content for this:

status Field within Standard Information in the information values within Normative element GAP element the field/IE action/comment <<Multi M Not used with keypad>> MMS <<Facility>> I Either this element or <<MMS>> element. Note 1. <Service 1 0 0 1 0 “Discriminator discriminator> for MMS service applications” <Components> Contains the MMS control information <<Calling- I Defines the MMS Party- message sender Number>> number. Note 1. <Number 0 1 1 “Network specific type> number” <Numbering Value depends on plan the interworked identification> network <<Called- I Defines the MMS Party- message recipient Number>> number <Number 0 1 1 “Network specific type> number” <Numbering Value depends on plan the interworked identification> network <<Called- I May contain Party- additional infor- Subaddress>> mation related to the recipient <Subaddress Value depends on type> the interworked network <Odd/Even> Value depends on the interworked network <<Time/ I Date information. date>> Note 1. <<MMS>> I Either this of <<Facility>> element contains the MMS control information. Note 1. NOTE 1. New coding(s)/element. See below:

The following frame is carried in the LAPU information field. The content is the same as in <<Alphanumeric>> element.

Field within the Information information element element Length Normative action/comment <<MMS 1-2 octets This field has the same sequence (7 bits used value as in the CC-INFO coding>> of each message carried at the octet) same time. <<Data 1 octet ( 7 This field has the same content bits used of value as in the CC-INFO type>> each octet) message carried at the same time. <Length of 1-4 octets This element is coded as contents> (7 bits used the User data length of each octet) <Character Coded as respective field in type> 8.2.8 <<Alphanumeric>> element. <Odd/Even> Coded as respective field in 8.2.8 <<Alphanumeric>> element. <Character set Coded as respective field in coding> 8.2.8 <<Alphanumeric>> element. <Data> Contains the message information Note that the first three elements are coded exactly like respective codings in CC-INFO (the bit 8 of each octet is used for element coding purposes).

There are three different cases: the call service change, call suspension, call resumption and service up/downgrading.

The call suspension illustrated in action 5 in FIGS. 25 and 26 and is done as described in the C.2 data profile Draft prETR 300 xxx. Version 5.00. Work Item No:DE/RES-03-030. Radio Equipment and Systems (RES); Digital European Cordless Telecommunications. Data Services Profile. Profile. Generic data link service. Service Type C, Class 2. European Telecommunications Standards Institute.20.1.1995. 260 pages and is optional.

The call resumption illustrated in action 5 in FIGS. 25 and 26 and is done as described in the C.2 data profile and is optional.

The action 5 in the FIGS. 25 and 26 can be the link up/down grading procedure. This message is used only when the E profile connection is upgraded to F.2 profile connection by initiating C.2 profile U-plane.

The following table shows the {CC-SERVICE-CHANGE} message content:

Field within Standard the values Information information within the element element field/IE Normative action/comment <<Service- Contains the service change change-info>> info <Change 0 0 1 0 Bandwidth change mode coding> <<Connection Contains the new attributes>> connection attributes <Symmetry> Connection related values. See 7.7.11 in ETS 300 175-5 <Connection 1 N N N Advanced connection identity number. The current coding> connection number. <Bearer Connection related values. definition See 7.7.11 in ETS 300 175-5 coding> <Number of 0 0 0 0 0 “No U-plane”. This value is bearer used when F profile is coding> downgraded to E. n n n n n Number of bearers. This field contains the requested bearer value when upgrading the E to F profile connection.

The procedure of up/downgrading between F- and C-data profiles is used for changing a bearer services (C-data profile) to a teleservice (F-data profile). A PP can initiate this type of procedure by sending a <<feature activate>> information element in the {CC-INFO} message. The <<feature activate>> element contains value “MMS service” in the <<Feature coding>> field. The Fixed part responses with {CC-INFO} message containing <<Feature indicate>> element with value “MMS Service” in the <<Feature coding>> field and “Activated” in the <<Status indicator>> to indicate successful MMS activation.

The following table shows the {CC-INFO} message content:

Field within Standard status the values Information in information within the Normative element GAP element field/IE action/comment <<Feature I In PP to FP direction activate>> <Feature x x x x “MMS activate”. Note 1. coding> <<Feature I In FP to PP direction indicate>> <Feature x x x x MMS indicate. Note 1. coding> NOTE 1. New coding(s)/element. See below.

The procedure of connection parameter negotiation is used to negotation IWU service related parameters or affect the IWU selection during the established connection or during the connection establishment. The procedure takes place by sending new reqested values in <<iwu-attributes>> element of the {CC-INFO} message. This procedure can be used also with other data profiles i.e. no MMS functionality is needed. The {CC-INFO} message with new values can be sent an message of its own (requesting IWU/parameter change), as a response to {CC-SETUP} message (reflecting new parameters for a connection i.e. service negotiation) or as a response a {CC-INFO} requesting IWU service/parameter change. An example of the usage of this functionalty in the case of GSM interworking is given below.

The following table shows the {CC-INFO} message content:

status Field within the Standard Information in information values within Normative element GAP element the field/IE action/comment <<lwu- I Note 1. attributes>> <Negotiation> 1 1 0 “Connection parameter negotiation”. Note 1. Other codings are done according to the requested service. NOTE 1. New coding(s)/element. See below.

The call release procedures are done as defined in the GAP profile.

The following M-MMS-SAP primitives are used in the MMS-API interface of the full-API model.

Primitive Req Cfm Ind Res M-MMS-SEND- x x x x M-MMS-RETRIEVE- x x M-MMS-CONTROL- x x x x

The M/C-MMS-SAP primitives of the full-API model are the same primitives as in C-MMS-SAP of half-API model but they are used directly by the M-MMS part.

Primitive Req Cfm Ind Res M-MMS-SETUP- x x M-MMS-CONNECT- x x x M-MMS-RELEASE- x x x x M-MMS-MODIFY- x x x

The rules how the M-MMS part uses the M/C-MMS-SAP are defined in each service interworking description.

The following M-MMS-SAP primitives are used in the MMS-API interface of the half-API model.

Primitive Req Cfm Ind Res M-MMS-SEND- x x x x M-MMS-RETRIEVE- x x M-MMS-CONTROL- x x x x

The following C-MMS-SAP primitives are used in the MMS-API interface of the half-API model.

Primitive Req Cfm Ind Res M-MMS-SETUP- x x M-MMS-CONNECT- x x x M-MMS-RELEASE- x x x x M-MMS-MODIFY- x x x M-MMS-GRADING- x x NOTE: M-MMS-GRADING- primitives are used for up/down grading the connection between C and F data profiles.

NOTE: M-MMS-GRADING- primitives are used for up/down grading the connection between C and F data profiles.

The non-API interface functionality is defined below.

The following DECT network layer Call Control primitives provide for MMS message transportation.

MNCC-INFO{req,ind}

In addition if the U-plane is used for data transmission the following DECT DLC layer U-plane primitive is used.

DLU-LU3_DATA {req, ind}

The MMS messages are conveyed by this primitive by containing the MMS messages in a parameter.

For MMS call control the following DECT network layer Call Control primitives will be used.

MNCC-SETUP—{req, ind}

MNCC-CONNECT—{req, cfm, ind}

MNCC-RELEASE—{req, cfm, ind, res}

MNCC-MODIFY—{req, cfm, ind}

MNCC-INFO{req, ind}

The MMS messages are conveyed by this primitive by containing the MMS messages in a parameter.

The mapping in the MMS-API case between M-MMS-SAP and NWK primitives in full and half-API models is done as follows:

MMS primitive MNCC primitive M-MMS-SEND{req, ind} MNCC-INFO{req, ind} M-MMS-RETRIEVE{req, ind} MNCC-INFO{req, ind} M-MMS-CONTROL-{req, MNCC-INFO{req, ind} ind}

The following mapping is done for the User data part (parameter) only in the case DECT U-plane is used. Other parameters are mapped as indicated before i.e. the User control data part is mapped to MNCC-INFO.

MMS primitive MNCC primitive M-MMS-SEND{req, ind} DLU-LU3_DATA{req, ind}

All other primitives are produced inside the MMS virtual layer.

The mapping of C-MMS primitives in the MMS-API case between C-MMS-SAP and NWK primitives is done as follows:

MMS primitive MNCC primitive M-MMS-SETUP-{req, ind} MNCC-SETUP-{req, ind} M-MMS-CONNECT-{req, cfm, ind} MNCC-CONNECT-{req, cfm, ind} M-MMS-RELEASE-{req, cfm, ind, MNCC-RELEASE-{req, cfm, ind, res} res} M-MMS-MODIFY-{req, cfm, ind} MNCC-MODIFY- {req, cfm, ind} M-MMS-GRADING-{req, cfm, ind} MNCC-INFO{req, ind}

The parameters depend on the content of the messages. The parameters and their values can be derived from the message contents as described herein.

The following new codings to the DECT network layer are preferred in order to provide MMS connections.

The purpose of the <<BASIC-SERVICE>> element (see Subclause 7.6.4 of ETS 300 175-5 2nd edition) is to indicate the basic aspects of the service requested. This element allows the user to indicate the use of default attributes, thereby reducing the length of the set-up message (see FIG. 27).

Call Class (Octet 2)

Bits 8 7 6 5 Meaning 1 0 0 0 Normal call set-up 1 0 0 1 Internal call (typically used in residential environments) 1 0 1 0 Emergency call set-up 1 0 1 1 Service call set-up 1 1 0 0 External handover call set-up (see subclause 9.3.1.1) 1 1 0 1 Supplementary service call set-up 1 1 1 0 Messaging service call setup

All other values reserved.

Basic Service (Octet 2)

Bits 4 3 2 1 Meaning 0 0 0 0 Basic speech default set-up attributes (NOTE and subclause 9.3.1.1) 0 1 0 0 DECT GSM IWP profile (Phase 2) 1 1 1 1 Other (see subclause 9.3.1.1)

All other values reserved.

NOTE: The value of this field may be used in future standards to indicate “specific profile default setup attributes”.

The purpose of the <<CALL-ATTRIBUTES>> element (see Subclause 7.7.5 in ETS 300 175-5 2nd edition) is to describe the higher layer service to be provided by the DECT protocol. The element may be repeated in a set-up message when using service negotiation (see FIG. 28).

Coding Standard (Octet 3)

Bits 7 6 Meaning 0 0 DECT standard coding

All other values reserved.

Network Layer Attributes (Octet 3)

Bits 5 4 3 2 1 Meaning 0 0 0 0 0 Undefined 0 0 0 0 1 Basic speech 0 1 0 0 0 DECT GSM IWP profile phase 2 0 1 1 0 0 DECT LRMS service profile (E data profile) 0 1 1 0 1 DECT MMS service profile (F data profile)

All other values reserved.

The following presentation of the IWU-ATTRIBUTES (see Subclause 7.7.21 in ETS 300 175-5 2nd edition) intends to expand the functionality of the element to be compatible also with other services than just ISDN connections. However the intention was to maintain compatibility with the older version. This proposed element contains also information carried in <<END-TO-END-COMPATIBILITY>> element. The purpose was to combine all information relating to the IWU selection to the same element. However, another option is to leave the <<END-TO-END-COMPATIBILITY>> element as a independent element and cut those overlapping part off from this element.

The purpose of the <<IWU-ATTRIBUTES>> element is to provide a means for service compatibility information to be exchanged (e.g. between a PP application and a FP interworking unit). This element is transferred transparently by the DECT protocol entities (see FIG. 29). Note—the octets 7-7 d could be left out and replaced by <<end-to-end compatibility>> element. In this case the references to the <<iwu-attributes>> element in this document means a reference to both <<iwu-attributes>> and <<end-to-end compatibility>>. Also, in this case both these elements should be added to the {CC-INFO} message in the case of connection parameter negotiation.

Coding Standard (Octet 3)

Bits 7 6 Meaning 0 0 DECT standard coding 0 1 Profile defined coding

All other values reserved.

Profile Coding (Oclet 3)

Bits 5 4 3 2 1 Meaning 0 0 0 0 0 A/B data profile 0 0 0 0 1 C data profile 0 0 0 1 0 D data profile 0 0 0 1 1 E data profile 0 0 1 0 0 F data profile

All other values reserved.

Negotiation Indicator (Octet 4)

Bits 7 6 5 Meaning 0 0 0 Negotiation not possible 1 0 0 Exchanged parameter negotiation 1 1 0 Connection parameter negotiation

All other values reserved.

Network Identity (Octet 5)

Bits 7 6 Meaning 0 0 octet identifier

All other values reserved.

External Connection Type (Octet 5)

Bits 4 3 2 1 Meaning 0 0 0 0 Not applicable 0 0 0 1 Connection oriented 0 0 1 0 Permanent Virtual Circuit 0 0 1 1 Non-permanent Virtual Circuit 0 1 0 0 Datagram 1 0 0 0 Connectionless

All other values reserved.

Network (Octet 5 a)

Bits 7 6 5 4 Meaning 0 0 0 0 Unspecified 0 0 0 1 PSTN 0 0 1 0 ISDN 0 0 1 1 GSM PLMN 0 1 0 0 DECT local network 1 0 0 0 CSPDN 1 0 0 1 PSPDN 1 0 1 0 Internet 1 0 1 1 Local Area Networks 1 1 0 0 B-ISDN 1 1 1 1 Reserved for extension

All other values reserved.

TE-network Interface (Octet 5 a)

Bits 3 2 1 Meaning 0 0 0 Not defined 1 0 0 Standard interface

All other values reserved.

External Service Type (Octet 5 b)

Bits 7 6 5 4 3 2 1 Meaning 0 0 0 0 0 0 0 Not specified 0 0 0 0 0 0 1 Any method 0 0 0 0 0 1 0 Address based IWU selection 0 0 0 0 0 1 1 A message handling facility 0 0 0 0 1 0 0 Physical 0 0 0 1 0 0 0 Voice telephone 0 0 0 1 0 0 1 Telex 0 0 0 1 0 1 0 Teletex 0 0 0 1 0 1 1 Facsimile group 3 0 0 0 1 1 0 0 Facsimile group 4 0 0 0 1 1 0 1 Videotex (T.100/T.101) 0 0 1 0 0 0 0 ERMES 0 0 1 0 0 0 1 National paging 0 0 1 0 0 1 0 UCI (ETS 300 133-3) 0 0 1 0 0 1 1 GSM SMS 0 0 1 0 1 0 0 DECT MMS 0 0 1 0 1 0 1 DECT LRMS 0 0 1 0 1 1 0 IA5 terminal 0 0 1 0 1 1 1 X.400 message handling 0 1 0 0 0 0 0 FTP 0 1 0 0 0 0 1 HTTP 0 1 0 0 0 1 0 Gopher 0 1 0 0 0 1 1 News 0 1 0 0 1 0 0 News/NNTP 0 1 0 0 1 0 1 Telnet 0 1 0 0 1 1 0 Wide area info server 0 1 0 0 1 1 1 Host specific file names 0 1 0 1 0 0 0 Prospero

All other values reserved.

LLC Identity (Octet 6)

Bits 7 6 Meaning 0 1 octet identifier

All other values reserved.

LLC Coding Indicator (Octet 6)

Bits 5 4 3 2 1 Meaning x x x x 1 LLC Information transfer attributes present x x x 1 x LLC Access attributes present x x 1 x x User information layer 1 protocol ID present x 1 x x x User information layer 2 protocol ID present 1 x x x x User information layer 3 protocol ID present

All other values reserved.

Information Transfer Capability (Octet 6 a)

Bits 5 4 3 2 1 Meaning 0 0 0 0 0 Speech 0 1 0 0 0 Unrestricted digital information 0 1 0 0 1 Restricted digital information 1 0 0 0 0 3.1 kHz audio 1 0 0 0 1 7.0 kHz audio 1 0 1 0 0 Fax 1 1 0 0 0 Video

All other values reserved.

Transfer Mode (Octet 6 b)

Bits 7 6 Meaning 0 0 Circuit mode 1 0 Packet mode 1 1 None (no transfer mode required)

All other values reserved.

Information Transfer Rate (Octet 6 b and 6e)

Bits 5 4 3 2 1 0 0 0 0 0 Packet mode calls 0 1 0 1 0 16 kbps 0 1 0 1 1 32 kbps 1 0 0 0 0 64 kbps 1 0 0 0 1 2 × 64 kbps 1 0 0 1 1 384 kbps 1 1 1 1 0 Unspecified 1 1 1 1 1 Defined by rate multiplier All other values reserved. NOTE 1: When octet 5c is omitted, the transfer rate is symmetric. When octet 5c is included, the rate in octet 5 refers to the direction Orig => Dest, and the rate in octet 5c refers to the reverse direction.

If the reserved coding “defined by rate multiplier” is used, then octet 5 a shall follow. Octet 5 d shall also follow if octet 5 c is used (i.e. for asymmetric rates).

Structure (Octet 5 b)

7 6 5 Meaning 0 0 0 Default 0 0 1 8 kHz integrity 1 0 0 SDU integrity 1 1 1 Unstructured

All other values reserved.

If octet 5 b is omitted, or the structure field is coded “default” the structure attribute shall be defaulted according to the following table:

Transfer mode Transfer capability Structure circuit speech 8 kHz integrity circuit restricted digital 8 kHz integrity circuit 3.1 kHz audio 8 kHz integrity circuit 7.0 kHz audio 8 kHz integrity circuit fax 8 kHz integrity circuit video 8 kHz integrity packet unrestricted digital SDU integrity

Configuration (Octet 6 d)

Bits 4 3 Meaning 0 0 point-to-point

All other values reserved.

Establishment (Octet 6 d)

Bits 2 1 Meaning 0 0 demand

All other values reserved.

Unit Rate (Octet 6 c and 6)

Bits 7 6 Meaning 0 1 16 kbps steps 1 0 32 kbps steps 1 1 64 kbps steps

All other values reserved.

Rate Multiplier (Octet 5 a and 5d)

Bits 5 4 3 2 1 Meaning 0 n n n n Number of steps All other values reserved. NOTE 2: The number of steps (nnnn) relates to the unit rate defined in the same octet. The value is coded with the natural binary value, with the least significant bit in bit position “1”. Allowable values for “number of steps” are “1” to “15”.

Symmetry (Octet 5 c)

Bits 7 6 Meaning 0 0 bidirectional symmetric 1 0 unidirectional asymmetric 1 1 bidirectional asymmetric

All other values reserved.

Rate Adaption (Octet 6)

Bits 5 4 Meaning 0 0 no rate adaption 0 1 C.110/X.30 rate adaption 1 0 CCITT X.31 flag stuffing

All other values reserved.

Signalling Access Protocol (Octet 7)

Bits 5 4 3 Meaning 0 0 1 I.440/450 0 1 0 X.21 0 1 1 X.28 - dedicated PAD, individual NUI 1 0 0 X.28 - dedicated PAD, universal NUI 1 0 1 X.28 - non dedicated PAD 1 1 0 X.32

All other values reserved.

Synchronous/asynchronous (Octet 7)

7 Meaning 0 synchronous 1 asynchronous

Negotiation (Octet 7)

Bits 6 Meaning 0 in-band negotiation not possible All other values reserved. NOTE: See Rec. V.110 and X.30

User Rate Coding (Oclet 7 a)

Bits 7 6 5 4 3 2 1 Meaning 0 0 0 0 0 0 1 0.6 kbps; V.6 and X.1. 0 0 0 0 0 1 0 1.2 kbps; V.6. 0 0 0 0 0 1 1 2.4 kbps; V.6 and X.1. 0 0 0 0 1 0 0 3.6 kbps; V.6. 0 0 0 0 1 0 1 4.8 kbps; V.6 and X.1. 0 0 0 0 1 1 0 7.2 kbps; V.6. 0 0 0 0 1 1 1 8.0 kbps; I.460. 0 0 0 1 0 0 0 9.6 kbps; V.6 and X.1. (GSM HSCSD) 0 0 0 1 0 0 1 14.4 kbps; V.6. (GSM HSCSD) 0 0 0 1 0 1 0 16 kbps; I.460. 0 0 0 1 0 1 1 19.2 kbps; V.6. (GSM HSCSD) 0 0 0 1 1 0 0 32 kbps; I.460. (GSM HSCSD) 0 0 0 1 1 1 0 48 kbps; V.6 and X.1. (GSM HSCSD) 0 0 0 1 1 1 1 56 kbps; V.6. 0 0 1 0 0 0 0 64 kbps; X.1. (GSM HSCSD) 0 0 1 0 1 0 1 0.1345 kbps; X.1. 0 0 1 0 1 1 0 0.1 kbps; X.1. 0 0 1 0 1 1 1 0.075/1.2 kbps; V.6 and X.1. (NOTE 5) 0 0 1 1 0 0 0 1.2/0.075 kbps; V.6 and X.1. (NOTE 5) 0 0 1 1 0 0 1 0.050 kbps; V.6 and X.1. 0 0 1 1 0 1 0 0.075 kbps; V.6 and X.1. 0 0 1 1 0 1 1 0.110 kbps; V.6 and X.1. 0 0 1 1 1 0 0 0.150 kbps; V.6 and X.1. 0 0 1 1 1 0 1 0.200 kbps; V.6 and X.1. 0 0 1 1 1 1 0 0.300 kbps; V.6 and X.1. 0 0 1 1 1 1 1 12 kbps; V.6. x x x x x x x 28.8 kbps; (GSM HSCSD) x x x x x x x 38.4 kbps; (GSM HSCSD) x x x x x x x 57.6 kbps; (GSM HSCSD) x x x x x x x 67.2 kbps; (GSM HSCSD) x x x x x x x 76.8 kbps; (GSM HSCSD) x x x x x x x 96 kbps; (GSM HSCSD) All other values reserved. NOTE 5: The first rate is the transmit rate in the forward direction of the call. The second rate is the transmit rate in the backward direction of the call. NOTE 6: See recommendations for CCITT X-series and CCITT I.460.

Intermediate Rate (Interm Rate) (Octet 7 b)

Bits 7 6 Meaning 0 0 Not used 0 1  8 kbps 1 0 16 kbps 1 1 32 kbps

Network Independent Clock on Transmission (NIC tx) (Octet 7 b)

Bits 5 Meaning 0 Not required to send data with network independent clock 1 Required to send data with network independent clock NOTE 7: NIC tx refers to transmission in the forward direction of the call. NOTE 8: See CCITT Recommendations V.110 and X.30.

Network Independent Clock on Reception (NIC rx) (Octet 7 b)

Bits 4 Meaning 0 Cannot accept data with Network independent clock 1 Required to send data with Network independent clock NOTE 9: NIC rx refers to transmission in the backward direction of the call. NOTE 10: See CCITT Recommendations V.110 and X.30.

Flow-Control on Transmission (F-C tx) (Octet 7 b)

Bits 3 Meaning 0 Not required to send data with flow control mechanism 1 Required to send data with flow control mechanism NOTE 11: F-C tx refers to transmission in the forward direction of the call.

Flow-Control on Reception (F-C rx) (Octet 7 b)

Bits 2 Meaning 0 Cannot accept data with flow control mechanism (i.e. sender does not support this optional procedure); 1 Can accept data with flow control mechanism (i.e. sender does support this optional procedure); NOTE 12: F-C rx refers to transmission in the backward direction of the call.

Stop Bits Coding (Octet 7 c)

Bits 7 6 Meaning 0 0 Not used 0 1   1 bit 1 0 1.5 bits 1 1   2 bits

Data Bits Coding (Octet 7 c)

Bits 5 4 Meaning 0 0 Not used 0 1 5 bits 1 0 7 bits 1 1 8 bits

Parity Coding (Octet 7 c)

Bits 3 2 1 Meaning 0 0 0 Odd 0 1 0 Even 0 1 1 None 1 0 0 Forced to 0 1 0 1 Forced to 1

All other values reserved.

Duplex Mode (Dup) (Octet 7 d)

Bits 7 Meaning 0 Half duplex 1 Full duplex

Modem Type (Octet 7 d)

Bits 6 5 4 3 2 1 Meaning 0 0 0 0 0 0 Reserved 0 0 0 0 0 1 V.21 0 0 0 0 1 0 V.22 0 0 0 0 1 1 V.22 bis 0 0 0 1 0 0 V.23 0 0 0 1 0 1 V.26 0 0 0 1 1 0 V.26 bis 0 0 0 1 1 1 V.26 ter 0 0 1 0 0 0 V.27 0 0 1 0 0 1 V.27 bis 0 0 1 0 1 0 V.27 ter 0 0 1 0 1 1 V.29 0 0 1 1 0 0 V.32 0 0 1 1 0 1 V.35 x x x x x x V.32 bis x x x x x x V.34 1 0 0 0 0 0 to } Reserved for national use 1 1 1 1 1 1 } All other values reserved. NOTE 13: CCITT V-series Recommendations

User Information Layer 1 Protocol (Octet 8)

Bits 7 6 5 4 3 2 1 Meaning 0 0 0 0 0 0 0 default layer 1 protocol

All other values reserved.

User Information Layer 2 Protocol (Octet 8 a)

Bits 5 4 3 2 1 Meaning 0 0 0 0 0 User specific (escape) 0 0 0 0 1 Basic mode ISO Publication 1745 0 0 0 1 0 CCITT Recommendation Q.921/I.441 (LAP.D) 0 0 1 1 0 CCITT Recommendation X.25; link layer (LAP.B) 0 0 1 1 1 CCITT Recommendation X.25 multilink 0 1 0 0 0 Extended LAP.B 0 1 1 0 0 ISO Publication 8802/2 (LAN LLC) 1 0 0 0 1 ISO Publication 8802/x [33] (NOTE 7) 1 0 0 1 0 GSM Recommendation 04.06) 1 0 1 1 0 CCITT Recommendation V.42 (LAP.M) 1 1 0 0 0 ISO 6429, codeset 0 (DC1/DC3) 1 1 0 0 1 X.75 layer 2 modified (teletex) 1 1 0 1 0 videotex profile 1 1 1 1 0 0 COPnoFICt (Character oriented Protocol with no Flow Control mechanism) 1 1 1 0 1 Internet Protocol All other values reserved. NOTE 4: ISO Publication 8802/x refers to LAN operation with a null Layer 2 protocol (LLC not implemented).

User Information Layer 3 Protocol (octet 8 b)

Bits 5 4 3 2 1 Meaning 0 0 0 0 0 User specific (escape) 0 0 0 1 0 ETS 300 102 0 0 1 1 0 CCITT Recommendation X.25 packet layer 0 0 1 1 1 ISO Publication 8208 (CCITT Recommendation X.25 packet level for DTE) 0 1 0 0 0 ISO Publication 8348 (OSI C/O protocol) 0 1 0 0 1 ISO Publication 8473 (OSI C/L service) 0 1 0 1 0 CCITT Recommendation T.70, minimum network layer 1 0 0 1 0 GSM Recommendation 04.08 0 0 0 0 1 Transmission Control Protocol

All other values reserved.

HLC Identity (Octet 9)

Bits 7 6 Meaning 1 0 octet group identifier

All other values reserved.

HLC Coding Indicator (Octet 9)

Bits 5 4 3 2 1 Meaning x x x x 1 User protocol ID present x x x 1 x User information layer 4 protocol ID present x x 1 x x User information layer 5 protocol ID present x 1 x x x User information layer 6 protocol ID present 1 x x x x User information layer 7 protocol ID present

User Protocol ID (Octet 9 a)

Bits 5 4 3 2 1 Meaning 0 0 0 0 0 User specific (escape) 0 0 0 0 1 V.110/X.30 rate adaption (NOTE 6) 0 0 0 1 0 G.711 μ-law PCM 0 0 0 1 1 G.711 A-law PCM 0 0 1 0 0 G.721 ADPCM 0 0 1 0 1 H.221 and H.242 0 0 1 1 0 H.261 Video 0 0 1 1 1 Non-standard rate adaption 0 1 0 0 0 V.120 rate adaption 0 1 0 0 1 X.31 rate adaption 1 0 0 0 0 Group 3 fax 1 0 0 0 1 Group 4 fax 1 1 0 0 0 X.28/X.29 1 0 0 1 0 GSM Recommendation 03.40, SM-TP messages [xx] 1 0 0 1 1 CCITT Recommendation X.400 messages [yy] 1 0 1 0 0 Internet RFC 822 or MIME messages [zz] 1 1 0 0 1 DECT LRMS/MMS protocol (MMSP) All other values reserved. NOTE 3: If octet 6 indicates “V.110/X.30 rate adaption”, the set-up message is also required to contain the <<END-TO-END-COMPATIBILITY>> element to define the attributes of the rate adaption service.

User Information Layer 4 Protocol (Octet 9 b)

Bits 5 4 3 2 1 Meaning

All other values reserved.

User Information Layer 5 Protocol (Octet 9 c)

Bits 5 4 3 2 1 Meaning

All other values reserved.

User Information Layer 6 Protocol (Octet 9 d)

Bits 5 4 3 2 1 Meaning

All other values reserved.

User Information Layer 7 Protocol (Octet 9 e)

Bits 5 4 3 2 1 Meaning

All other values reserved.

QoS Identity (Octet 10)

Bits 7 6 Meaning 1 1 octet group identifier

All other values reserved.

The purpose of the <<FACILITY>> information element (see Subclause 7.7.15 in ETS 300 175-5 2nd edition) is to indicate the invocation and operation of supplementary services, identified by the corresponding operation value within the <<FACILITY>> information element (see FIG. 30).

Service Discriminator Coding

Bits 5 4 3 2 1 Meaning 1 0 0 0 1 Discriminator for supplementary service applications 1 0 0 1 0 Discriminator for Multimedia Messaging service applications

All other values are reserved.

Other fields are coded as indicated below.

The purpose of the <<CALLED-PARTY-NUMBER>> element (see Subclause 7.7.7 in ETS 300 175-5 2nd edition)is to identify the called party of a call in an en-bloc format (see FIG. 31).

Number Type (Octet 3)

Bits 7 6 5 Meaning 0 0 0 Unknown 0 0 1 International number 0 1 0 National number 0 1 1 Network specific number 1 0 0 Subscriber number 1 0 1 Server number 1 1 0 Abbreviated number 1 1 1 Reserved for extension

All other values reserved.

Numbering Plan Identification (Octet 3)

Bits 4 3 2 1 Meaning 0 0 0 0 Unknown 0 0 0 1 ISDN/telephony plan Rec. E.164/E.163 0 0 1 1 Data plan Rec. X.121 1 0 0 0 National standard plan 1 0 0 1 Private plan 1 0 1 0 IP Address 1 0 1 1 IP Address Character format (URI) 1 1 0 0 X.400 address 1 1 0 1 URI 1 1 1 0 LAN address 1 1 1 1 Reserved for extension All other values reserved. NOTE: DECT characters are specified below. They are based on IA5 characters.

MMS Protocol Element

Bits 8 7 6 5 4 3 2 1 Octet: 0 < <MMS protocol element> > 1 Length of Contents (L) 2 1 MMS Action type Rep. Esc 3 0/1 MMS sequence number 4 1 MMS sequence numbering (extension) 4a 0/1 Service type 5 0/1 Service subtype Transmission 6 type 0/1 Data content type 7 0/1 Action result 8 0/1 Command type 9 0/1 Information type 10 0/1 Command object 11 0/1 Command object (extension) 11a 0/1 User data length 12 0/1 User data length (extension) 12a 0/1 User data length (extension) 12b 1 User data length (extension) 12c

MMS Action Type (Octet 3)

Bits 7 6 5 4 Meaning 0 0 0 1 MMS-SEND 0 0 1 0 MMS-SEND-RPY 0 0 1 1 MMS-RECEIVE 0 1 0 0 MMS-RECEIVE-RPY 1 0 0 0 MMS-CONTROL 1 0 0 1 MMS-CONTROL-RPY 1 0 1 0 MMS-STATUS 1 0 1 1 MMS-STATUS-RPY

All other values reserved.

Replay Requested (Octet 3)

Bits 3 2 Meaning x 0 Reply not requested from MMS entity x 1 Reply requested from MMS entity 0 x Reply not requested from end entity 1 x Reply requested from end entity

All other values reserved.

Escape Command Present (Octet 3)

Bits 1 Meaning 0 Escape command not present 1 Escape command present

All other values reserved

MMS Sequence Number (Octet 4)

Coded as natural binary value. Value 0 is reserved for general use.

Extended MMS Sequence Number (Octet 4 a)

Coded as octet 4. This octet is optional. The complete MMS sequence number is a combination of both octets.

Service Type (Octet 5)

Bits 7 6 5 4 3 2 1 Meaning 0 0 0 0 0 0 0 Not specified 0 0 0 0 0 0 1 Any method 0 0 0 0 0 1 0 Address based IWU selection 0 0 0 0 0 1 1 A message handling facility 0 0 0 0 1 0 0 Physical 0 0 0 1 0 0 0 Voice telephone 0 0 0 1 0 0 1 Telex 0 0 0 1 0 1 0 Teletex 0 0 0 1 0 1 1 Facsimile group 3 0 0 0 1 1 0 0 Facsimile group 4 0 0 0 1 1 0 1 Videotex (T.100/T.101) 0 0 1 0 0 0 0 ERMES 0 0 1 0 0 0 1 National paging 0 0 1 0 0 1 0 UCI (ETS 300 133-3) 0 0 1 0 0 1 1 GSM SMS 0 0 1 0 1 0 0 DECT MMS 0 0 1 0 1 0 1 DECT LRMS 0 0 1 0 1 1 0 IA5 terminal 0 0 1 0 1 1 1 X.400 message handling 0 1 0 0 0 0 0 FTP 0 1 0 0 0 0 1 HTTP 0 1 0 0 0 1 0 Gopher 0 1 0 0 0 1 1 News 0 1 0 0 1 0 0 News/NNTP 0 1 0 0 1 0 1 Telnet 0 1 0 0 1 1 0 Wide area info server 0 1 0 0 1 1 1 Host specific file names 0 1 0 1 0 0 0 Prospero

All other values reserved.

Service Subtype (Octet 6)

Bits 7 6 5 4 Meaning 0 0 0 0 Undefined 0 0 0 1 Standard

Telex

0 0 0 1 Standard 1 1 0 0 Via teletex conversion

Teletex

0 0 0 1 Standard 0 0 1 0 Oper. doc. 0 0 1 1 Monit doc 0 1 0 0 Ctrl doc. 0 1 0 1 TFT of Doc. tr. Mode 0 1 1 0 TFT of Binary File Tr. 0 1 1 1 TFT of Edifact 1 0 0 0 in PSPDN 1 0 0 1 in CSPDN 1 0 1 0 in analog PSTN 1 0 1 1 in digital ISDN

Facsimile Group 3

0 0 0 1 Standard 1 1 0 1 TFT of Basic tr. Mode 0 1 0 1 TFT of Doc. tr. Mode 0 1 1 0 TFT of Binary File Tr. 0 1 1 1 TFT of Edifact

Facsimile Group 4

0 0 0 1 Standard 0 0 1 0 Oper. doc. 0 0 1 1 Monit doc 0 1 0 0 Ctrl doc. 0 1 0 1 TFT of Doc. tr. Mode 0 1 1 0 TFT of Binary File Tr. 0 1 1 1 TFT of Edifact

All other values reserved.

These values are related to the Service type field i.e. not all listed values are possible with all service type options. The service options related to the value of the Service type is defined. (TFT; Telematic File Transfer).

Message Transmission Type (Octet 6)

Bits 3 2 1 Meaning 0 0 1 Unspecified 0 1 0 Encapsulated 0 1 1 Multipart 1 0 0 Body in U-plane 1 0 1 Header in C-plane 1 1 0 Normal

All other values reserved.

Message Content Type (Octet 7)

Bits 7 6 5 4 3 2 1 Meaning 0 0 0 0 0 0 0 Undefined 0 0 0 0 0 0 1 Specified by the service type 0 0 0 0 0 1 0 Local type 0 0 0 0 0 1 1 Simple formattable document 0 0 0 0 1 0 0 Basic text 0 0 0 0 1 0 1 IA 5 text (T.50) 0 0 0 0 1 1 0 Telex 0 0 0 0 1 1 1 Teletex (T.61) 0 0 0 1 0 0 0 Videotex (T.100/T.101) 0 0 0 1 0 0 1 Image 0 0 0 1 0 1 0 TIFF image 0 0 0 1 0 1 1 GIF image 0 0 0 1 1 0 0 JPEG image 0 0 0 1 1 0 1 Fax G 4 class 1 0 0 0 1 1 1 0 Fax G 3 (T.4/T.30) 0 0 1 0 0 0 0 Audio 0 0 1 0 0 0 1 AVI audio 0 0 1 0 0 1 0 Multipart: mixed 0 0 1 0 0 1 1 Multipart: parallel 0 0 1 0 1 0 0 Multipart: alternative 0 0 1 0 1 0 1 Multipart: digest 0 0 1 0 1 1 0 Encapsulated: RFC 822 or MIME 0 0 1 0 1 1 1 Encapsulated: GSM SMS 0 0 1 1 0 0 0 Encapsulated: X.400 0 0 1 1 0 0 1 Octet stream application 0 0 1 1 0 1 0 Postscript application 0 0 1 1 0 1 1 Video 0 0 1 1 1 0 0 MPEG video 0 0 1 1 1 0 1 AVI video

All other values reserved.

This field specifies the content of the message i.e. the format of the message content.

Action Result (Octet 8)

Bits 7 6 5 4 3 2 1 Meaning Successful transactions: 0 0 0 0 0 0 0 Message received by server 0 0 0 0 0 0 1 Message sent to end entity 0 0 0 0 0 1 0 Message replaced by the server 0 0 0 0 0 1 1 Message received by end entity Temporary Error: 0 1 0 0 0 0 0 Congestion 0 1 0 0 0 0 1 End entity busy 0 1 0 0 0 1 0 No response from end entity 0 1 0 0 1 0 0 Quality of service not available 0 1 0 0 1 0 1 Error in end entity 0 1 0 0 1 1 0 No memory available Permanent Error: 1 0 0 0 0 0 1 Invalid address 1 0 0 0 0 1 1 Invalid network(End User not accessible) 1 0 0 0 0 1 0 End entity not available 1 0 0 0 1 0 1 Secondary interworking failed 1 0 0 0 1 1 0 Primary interworking failed 1 0 0 0 1 1 1 Incompatible file type 1 0 0 1 0 0 0 Service rejected General values: 1 0 0 0 0 0 0 Command successful 1 0 0 0 0 0 1 Command unsuccessful 1 0 0 0 0 1 0 Successful 1 0 0 0 0 1 1 Unsuccessful

All other values reserved.

Command Type (Octet 9)

Bits 7 6 5 4 3 2 1 Meaning Message related: 0 0 0 0 0 0 0 Status Enquiry 0 0 0 0 0 0 1 Cancel status enquiry 0 0 0 0 0 1 0 Delete 0 0 0 0 1 0 0 Replace 0 0 0 0 1 0 1 Memory available 0 0 0 0 1 1 0 Cancel Connection related: 0 0 1 0 0 0 0 Login 0 0 1 0 0 0 1 Logout

All other values reserved.

Information Type (Octet 10)

Bits 7 6 5 4 3 2 1 Meaning 0 0 0 0 0 0 0 Status report 0 0 0 0 0 0 1 Message/file waiting in server

All other values reserved.

Command Object (Octet 11 . . . 11 a)

Coded as MMS Sequence Numbering

User Data Length (Octet 12, 12 a, 12 b, 12 c)

Coded as natural binary value indicating the amount of octets in the user data field.

Time/Date Element

Bits 8 7 6 5 4 3 2 1 Octet: 0 < < Time/Date > > 1   Length of Contents (L) 2   Year 3   Month 4   Day 5   Hour 6   Minute 7   Second 8   Time zone 9

Time/date Coding

Year: Month: Day: Hour: Minute: Second: Time Zone Digits: 2 2 2 2 2 2 2 (Semi-octets)

The Time Zone indicates the difference, expressed in quarters of an hour, between the local time and GMT. In the first of the two semi-octets, the first bit (bit 3 of the seventh octet of the TP-Service-Centre-Time-Stamp field) represents the algebraic sign of this difference (0: positive, 1: negative). The Service-Centre-Time-Stamp, and any other times coded in this format, represents the time local to the sending entity. The Time Zone code enables the receiver to calculate the equivalent time in GMT from the other semi-octets in the Service-Centre-Time-Stamp, or indicate the time zone (GMT, GMT+1H etc.), or perform other similar calculations as required by the implementation.

The purpose of the <<ALPHANUMERIC>> element (see Subclause 7.7.3 in ETS 300 175-5 2nd edition) is to provide a transport mechanism for a family of alternative characters in both directions.

NOTE: This element shall not be used to carry dialing information.

This element shall not be used to carry dialling information (see FIG. 32).

Character Type Coding

Value Bits Meaning 7 6 5 (Character type) 0 0 1 Standard 8-bit characters 0 1 0 Standard 4-bit characters 0 1 1 Standard 7 bit characters 1 0 0 Binary 1 0 1 Compressed 1 1 0 Encrypted 1 1 1 Others

All other values reserved.

Odd/even Coding

Bits 4 Meaning 0 Even number of characters 1 Odd number of characters NOTE: The odd/even flag shall only be used when the character type is 4 bit. In all other cases it should be set to “even”.

Standard 8-bit Character Set Coding

Character Set Coding

Value Bits Meaning 3 2 1 (Character set) 0 0 0 Reserved 0 0 1 DECT standard 8 bit 0 1 0 8 bit ASCII 0 1 1 US-ASCII 1 0 0 ISO 8859 1 0 1 8 bit EBCDIC

All 8-bit characters shall always be coded with one character per octet. Multiple characters shall be interpreted in the order of ascending octet numbers.

Standard 4-bit Character Set Coding

Character Set Coding

Value Bits Meaning 3 2 1 (Character set) 0 0 0 Reserved 0 0 1 WCPE standard 4-bit characters (Annex D) 1 0 0 ERMES 4-bit characters (ANSI/TIA Standard [27])

All other values reserved.

4-bit characters shall always be coded with two characters per octet. Multiple characters shall be interpreted in the order of ascending octet numbers, and within each octet the high placed character (bits position 5-8) first.

7 Bit Characters Set Coding

Character Set Coding

Value Bits Meaning 3 2 1 (Character set) 0 0 0 7 bit ERMES 0 0 1 7 bit standard ASCII 0 1 0 7 bit ASCII (IA5/T.50)

All other values reserved.

Others Characters Set Coding

Character Set Coding

Value Bits Meaning 3 2 1 (Character set) 0 0 0 ASN.1. BER.1 0 0 1 User specific 0 1 0 National variations of IRA

All other values reserved.

Compressed Characters Set Coding

Character Set Coding

Value Bits Meaning 3 2 1 (Character set) 0 0 0 ZIP 0 0 1 V.42 bis

All other values reserved.

Encrypted Characters Set Coding

Character Set Coding

Value Meaning Bits 3 2 1 (Character set)

All other values reserved.

The language coding defined in octet 5 is optional. The coding is done as specified in GSM 03.38.

The purpose of the <<SERVICE-CHANGE-INFO>> element (see Subclause 7.7.38 in ETS 300 175-5 2nd edition) is to indicate the attributes of the proposed service change (see FIG. 33).

Coding Standard

Bits 7 6 Meaning 0 0 DECT standard coding

All other values reserved.

M (Master) Coding

Bits 5 Meaning 0 Initiating side is master 1 Receiving side is master

Change Mode Coding

Bits 4 3 2 1 Meaning 0 0 0 0 None 0 0 0 1 Connection Reversal 0 0 1 0 Bandwidth change (NOTE 1) 0 1 0 0 Rerouting (of U-plane links) (NOTE 1) 0 1 1 0 Rerouting plus bandwidth change (NOTE 1) 1 0 0 0 Suspend 1 0 0 1 Resume 1 1 1 1 Reserved for extension (NOTE 2)

All other values reserved.

NOTE 1: Additional information elements shall be included in the message when indicating “bandwidth change” or “rerouting”. Refer to subclause 9.6. NOTE 2: When using the reserved value, octet 3 a shall follow containing extended coding of the service change. NOTE 3:Octet 4 shall only appear for “suspend” and “resume” codings. Octet 4 shall only appear for “suspend” and “resume” codings.

Extended Change Mode

Extended change mode is reserved for further standardisation.

A Attributes Coding

Bits 7 6 5 Meaning 0 0 0 Not applicable 0 1 0 Maintain old connection(s) 0 1 1 Release old connection(s)

Reset (R) Coding

Bits 4 Meaning 0 Do not reset state variables 1 Reset state variables

B Attributes Coding

Bits 3 2 1 Meaning 0 0 0 Not applicable 0 1 0 Interrupt data transfer 0 1 1 Maintain data transfer

The purpose of the <<FEATURE-ACTIVATE>> information element (see Subclause 7.7.16 in ETS 300 175-5 2nd edition) is to activate a feature as identified in the feature field (see FIG. 34).

Feature Coding (Octet 3)

Bits 7 6 5 4 3 2 1 Meaning Parameter 0 0 0 0 0 0 1 register recall no 0 0 0 1 1 1 1 external handover switch no 0 1 0 0 0 0 0 queue entry request no 0 1 1 0 0 0 0 indication of subscriber no number 1 0 0 0 0 1 0 feature key yes 1 0 0 0 1 0 0 specific line selection yes 1 0 0 0 1 1 1 specific trunk carrier yes selection 1 0 0 1 0 0 0 control of echo control yes functions 1 1 0 0 0 0 0 cost information yes 1 1 1 0 0 0 0 MMS messaging no

All other values reserved.

The purpose of the <<FEATURE-INDICATE>> information element (see Subclause 7.7.17 in ETS 300 175-5 2nd edition) is to allow the FT to convey feature indications to the user regarding the status of an activated feature (see FIG. 35).

Feature Coding (Octet 3)

Bits 7 6 5 4 3 2 1 Meaning Parameter 0 0 0 0 0 0 1 register recall no 0 0 0 1 1 1 1 external handover switch no 0 1 0 0 0 0 0 queue entry request no 0 1 1 0 0 0 0 indication of subscriber no number 1 0 0 0 0 1 0 feature key yes 1 0 0 0 1 0 0 specific line selection yes 1 0 0 0 1 1 1 specific trunk carrier yes selection 1 0 0 1 0 0 0 control of echo control yes functions 1 1 0 0 0 0 0 cost information yes 1 1 1 0 0 0 0 MMS messaging no

All other values reserved.

The purpose of the <<IWU-TO-IWU>> element (see Subclause 7.7.23 in ETS 300 175-5 2nd edition) is to encapsulate any message or information element that cannot be interworked into one or more other DECT information element(s).

If the message or element is too large to fit into a single <<IWU-TO-IWU>> element, it shall be segmented into a series of <<IWU-TO-IWU>> elements that are associated using the <<SEGMENTED-INFO>> element (see FIG. 36).

Send/Reject (SIR) Bit

Bits 7 Meaning 0 Rejection of message 1 Transmission of message NOTE 1: This Send/Reject (S/R) bit is used to distinguish between the sending of a new message (e.g. sent in the direction A = > B) and the rejection of a received message (e.g. message received by B can be rejected by sending “reject” code in direction B = > A).

Protocol Discriminator (PD)

Bits 6 5 4 3 2 1 Meaning 0 0 0 0 0 0 User Specific (NOTE 2) 0 0 0 0 0 1 OSI high layer protocols 0 0 0 0 1 0 CCITT Recommendation X.244 [37] (NOTE 3) 0 0 0 1 0 0 IA5 characters [25] 0 0 0 1 1 1 CCITT Recommendation V.120 Rate adaption 0 0 1 0 0 0 CCITT Recommendation Q.931 (I.451), message [30] 0 0 1 0 0 1 CCITT Recommendation Q.931 (I.451), element(s) [30] (NOTE 4) 0 0 1 0 1 0 CCITT Recommendation Q.931 (I.451), partial message. (NOTE 5) 0 1 0 0 0 0 GSM Recommendation 04.08, message [22] 0 1 0 0 0 1 GSM Recommendation 04.08, element(s) [22] (NOTE 4) 0 1 0 0 1 0 GSM Recommendation 03.40, SM-TP messages [xx] 0 1 0 0 1 1 CCITT Recommendation X.400 messages [yy] 0 1 0 1 0 0 Internet RFC 822 or MIME messages [zz] 1 1 1 1 1 1 Unknown

All other values reserved.

NOTE 2:The IWU information is structured as shown below. NOTE 3:The IWU information is structured according to CCITT RecommendationX.244[37] (CCITT RecommendationX.25[67] call user data). NOTE 4:If more than one element is included, they are interpreted in the order of appearance.NOTE 5: The Q.931(I.451) partial message excludes the protocol discriminator and the call

Rest of the subclause 7.7.23 remains the same.

The CC-INFOrmation (see Subclause 6.3.2.2 of ETS 300 175-5 2nd edition) message is used to transfer additional information between FT and PT both during and after call establishment (see FIG. 37). NOTE 1:The message may contain either the <<CALLED-PARTY-NUMBER>> element or the <<“KEYPAD”>> element, but not both. NOTE 2: Included if the PT optionally indicates completion of “OVERLAP SENDING” to the FT (or if the FT optionally indicates completion of “OVERLAP RECEIVING” to the PT). NOTE 3: Address elements are only included in messages sent in the “OVERLAP SENDING” state. NOTE 4:Included if requested as part of external handover. NOTE 5:The <<REPEAT-INDICATOR>> information element may optionally be included in front of the <<FACILITY>>, <<IWU-to-IWU>> and <<PROGRESS INDICATOR>> information elements indicating “non-prioritised list”. NOTE 6:The <<IWU-ATTRIBUTES>> element is used only in connection paramter negotiation and the element can only be if <<MMS protocol>> element or <<Facility>> element are not present.

The following illustrates the interworking of the MMS to alternate services. Only general interworking is described.

The interworking can take place in two different ways: a complete interworking when the upper protocol layers of the service are conveyed transparently and the user may receive the original service or all layers are mapped to the MMS and the user receives the original service via MMS service. MMS provides capability for both of these. Mapping proposed below give a rough proposal for mappings with no details.

The GSM SMS interworking takes place on the GSM protocol leves of SM-TP and SM-RP. The E-data profile is used. When an MMS call is established the GSM Short message service center number is received in {CC-SETUP} message and it is used in the SM-RP layer messages in the RP-Destination Address field. In the case of Mobile terminated messaging the RP-Originating Address information is mapped into {CC-SETUP} message <<Calling pary number>> element. The contents of the SM-TP layer frame is mapped into MMS messages. A special case of the RP-SMMA message is conveyed in the MMS-COMMAND messages.

The RP layer (“Successful” in MMS) and TP layer (“End entity received message” in MMS) acknowledgements are done with MMS messaging replies. Thus the interworking in the GSM case is between MMS and SM-TP and SM-RP (see FIG. 38).

The interworking of DECT MMS and GSM facsimile group 3 takes place with the T.30 fax service. The fax received from PP/outside network is first received by the FP, the formed for the other transmission format (T.30 or MMS) and transmited further. The terminal (PP) can disconnect the air interface connection after the FP has received the fax and the FP may inform the PP by sending a short message through E profile about the successful delivery of the fax. Also the FP may inform the PP about incoming fax by short messaging. The terminal can the upgrade the E profile connection into a full F-profile fax connection to receive the fax transmission (see FIG. 39).

The interworking of DECT MMS and PSTN facsimile group 3 takes place with the T.30 fax service. The services procedures are as in GSM case but the implementation from technical perspective is just like a Local area network fax server case. The FP may contain a computer with a fax server card which takes care of the fax transmission and reception to/from outside world (see FIG. 40).

The interworking of DECT MMS and internet HTTP (WWW) interworking takes place only between HTTP protocol and MMS. During the call establsihment the proxy server address is defiend (if needed) in the {CC-SETUP} message. If login procedures to the server are needed the MMS control procedures are used. The actual MMS commands are mapped into the HTTP commands. The files are trasferred through the U-plane connection (F-profile) and the commands through C plane (see FIG. 41).

The interworking of DECT MMS and internet FTP takes place only between FTP protocol and MMS. During the call establishment the FTP server address (Internet address) is defined (if needed) in the {CC-SETUP} message. If login procedures to the server are needed the MMS control procedures are used. The actual MMS commands are mapped into the HTTP commands. The files are trasferred through the U-plane connection (F-profile) and the commands through C plane (see FIG. 42).

The interworking of DECT MMS and X.400 takes place between X.400 P3/P.7 protocols and MMS. In this case the User Agent (UA) can be in the PP. Thus the MMS replaces the P3/P7 protocol in the air interaface. The body part of the mail is trasferred through the U-plane connection (F-profile) and the protocol control information through the C-plane (see FIG. 43).

The following table classifies the different actions of the alternate message/file transfer services for interworking of messages and proposes a common MMS action that could be interworked to the all services.

MMS CCITT X.400 action T.611 GSM SMS HTTP FTP (P3) Comment MMS- SEND RP-DATA PUT STOR Message- Sending SEND (SMS- POST NOOP submission message/ DELIVER and the Probe- file or file submission SMS- Message- SUBMIT) delivery MMS- SEND RP-ERROR HTTP FTP Message- The SEND- response (SMS- response reply submission acknowledge- RPY DELIVER- Result ment of the REPORT transmission or SMS- SUBMIT- REPORT) or RP-ACK MMS- RECEIVE — GET RETR X.400 P7 Fetching a RETRIEVE HEAD has this file or feature message (FETCH) MMS- RECEIVE — HTTP FTP X.400 P7 The response RETRIEVE- response response reply has this of fetch RPY and the feature received (FETCH) file MMS- TRACE RP-DATA DELETE USER Cancel- Control COMMAND delete, (SMS- LINK QUIT deferred- info to copy, COMMAND) UNLINK PORT delivery control the cancel, RP- TYPE Submission- remote purge, SMMA MODE control file/message reschedule, STRU Register or to dispatch Change- receive/send credentials status/control Report- information delivery MMS- RP-DATA STATUS (SMS- STATUS- REPORT) MMS- TRACE RP-ERROR HTTP FTP Acknowledge COMMAND- response (SMS- response reply -ment of the RPY SUBMIT- action or REPORT) MMS- or STATUS- RP-ACK RPY NOTE: The GSM SMS service requirements are based on the both SM-RP and SM-TP layers since the actual funtionality of the GSM short messaging is a combination of these both, for instance, the acknowldegement of the SM-TP layer messages is done by the SM-RP layer. MMS-SEND action can replace both SMS-DELIVER and SMS-SUBMIT since it may convey information to both directions. The parenthesis in the column indicate that RP layer message is carrying the TP layer message.

The following table lists the fields of each service that should be mapped in the direction of PP to FP for MMS-SEND interworking to T.611 Fax, GSM SMS, FTP, CCITT X.400 and HTTP. (o) indicates an optional field.

GSM X.400 MMS T.611 SMS GSM SMS HTTP FTP (P3) MMS- SEND SMS- SMS- PUT STOR Message- SEND DELIVER SUBMIT submission USER CONTROL PART Action Function TP- TP- Method Command Operation type Message- Message- Type- Type- Indicator Indicator Reply Sendack TP- TP-Status- Acknow- Acknow- Originator- request variation Status- Report- ledge ledge report- is used Report- Request should should request or not Indicator always be always be used used MMS REQ-ID — TP- Message — Message- sequence Message- ID token (o) number reference Service Service TP- TP- URL — Requested- type ID Protocol- Protocol- scheme delivery- Identifier Identifier method (o) Service Type ID TP- TP- — — — subtype Protocol- Protocol- Identifier Identifier Message — — — Content — — transm.type type Data Convert TP- TP- Content- Type Content- content Protocol- Protocol- Type coding Type type Identifier Identifier Content- Mode subtype coding Time Send TP- TP- Date (o) — Deferred- Stamp time Service- Validity- delivery- center- Period time (o) time- stamp Recipient Address — TP- URI — Recipient- address Destination- name Address Sender LA-ID ? TP- — From — Originator- address Originating- name Address Segmented — — — Content — — info type = Multipart this is used USER DATA PART Character APPLI/ TP-Data- TP-Data- Char set Char set Encoding type COM Coding- Coding- info type coding header Sceme Sceme Code Id Character APPLI/ TP-Data- TP-Data- Char set Char set Encoding set coding COM Coding- Coding- info type header Sceme Sceme Code Id Language — — — — — — coding User data File size TP-User- TP-User- Content — — length Data- Data- Length Length Length User data The file TP-User- TP-User- Entity The file Content referred Data Data Body referred with with Filename Pathname in stream mode

The following table lists the fields of each service that should be mapped in the direction of PP to FP for MMS-SEND-RPY interworking to T.611 Fax, GSM SMS, FTP, CCITT X.400 and HTTP. (o) indicates an optional field.

MMS T.611 GSM SMS GSM SMS HTTP FTP X.400 (P3) MMS- SEND RP- RP-ACK HTTP FTP Message- SEND- response ERROR(SMS- response reply submission- RPY DELIVER/ result SUBMIT- REPORT) Action Function RP- RP- Method — Messge- type Message- Message- submission- Type- Type- identifier Indicator Indicator MMS REQ-ID RP- RP- Message — — sequence Message- Message- ID number Reference Reference Action Status RP-Cause or — Status- Status- — result Error TP-Failure- Code Code Cause

The following table lists the fields of each service that should be mapped in the direction of PP to FP for MMS-RETRIEVE interworking to T.611 Fax, FTP, CCITT X.400 and HTTP. (o) indicates an optional field.

Field in MMS- RETRIEVE T.611 HTTP FTP X.400 (P7) USER RECEIVE GET RETR Fetch CONTROL HEAD PART Action type Function Method Command Operation Reply Always Always Always Always request used used used used MMS REQ-ID — — — sequence number Service Service — type Intermediate Address of — — — server the Fax address service in the network MMS Filename Filename Filename Item sequence number Data Convert Content- — Content- content Type Type type Command — — — — type

The following table lists the fields of each service that should be mapped in the direction of PP to FP for MMS-RETRIEVE-RPY interworking to T.611 Fax, FTP, CCITT X.400 and HTTP. (o) indicates an optional field.

Field in MMS- RETRIEVE- RPY T.611 HTTP FTP X.400 (P7) USER RECEIVE HTTP FTP reply Fetch CONTROL response response result PART Action type Function Method — Operation MMS REQ-ID Message ID — Sequence- sequence number number Service type Service (o) — — — Network Address (o) — — — address (address type) Message — Content — — transmission type type Data Type (o) Content Type code Content content type Convert type Mode type Content code subtype Action Error Status- Status- Entry result Code Code status MMS — — — — sequence number Time Stamp Send Date (o) — — time (o) Segmented — If Content — info type = Multipart this is used USER DATA PART Character APPLI/COM Char set — — type coding header Code Id Character APPLI/COM Char set — — set coding header Code Id Language — — — — coding User data Length of Content — Content- length the file Length length User data The file Entity Body The Content referred Filename with data in Filename stream mode

The following table lists the fields of each service that should be mapped in the direction of PP to FP for MMS-COMMAND interworking to T.611 Fax, GSM SMS, FTP, CCITT X.400 and HTTP. (o) indicates an optional field.

Field in MMS- X.400 COMMAND T.611 GSM SMS GSM SMS HTTP FTP (P3/P7) USER TRACE SMS- RP-SMMA DELETE USER Cancel- CONTROL COMMAND LINK QUIT deferred- PART UNLINK PORT delivery TYPE Submission- MODE control STRU Register Change- credentials Report- delivery Delete Action type Function TP- RP- Method Command Operation Message- Message- Type- Type Indicator Reply Sendack Acknow- — Acknow- Acknow- — request variation ledge ledge ledge is should should should used or always be always always not used be used be used MMS REQ-ID TP- RP- Message — — sequence Message- Message- ID number Reference Reference Service type — TP- — URL — — protocol-ID scheme Time Stamp Sendtime — — Date (o) — Deferred- delivery- time (o) Intermediate — — — Host- — server port address User data — TP- — Content Type Content content protocol-ID type code types Content Mode subtype code Command REQREF TP- — Request — Message object (MMS Message- URI — seq) Number submission- identifier Command Function TP- “Memory Method Command Operation type Command- available Type coding” is used. Escape — TP-User- TP-User- — — — commands/ Data- Data- information Length Length present Control data — TP- — — — — length Command- data-length Control data — TP- — — User User Command- name name data New and Old credentials

The following table lists the fields of each service that should be mapped in the direction of PP to FP for MMS-COMMAND-RPY interworking to T.611 Fax, GSM SMS, FTP, CCITT X.400 and HTTP. (o) indicates an optional field.

GSM X.400 MMS T.611 GSM SMS SMS HTTP FTP (P3) MMS- TRACE RP-ERROR RP-ACK HTTP FTP Operation COMMAND- response (SMS- response reply results RPY SUBMIT- REPORT) Action type Function RP or TP RP- — — Operation Message- Message- Type- Type- Indicator Indicator MMS REQ-ID RP- RP- — — — sequence Message- Message- number Reference Reference Time Send — — — — — Stamp time (o) Command — — — — — object Command — — — — — type Action Error RP-Cause Value of Status- Status- Values of result or TP- “Success- Code Code MMS is Failure- ful” of used to Cause MMS is indicate used error or success Control — — — — — data length Control — — — — — data

The following table lists the fields of each service that should be mapped in the direction of PP to FP for MMS-STATUS interworking to GSM SMS and X.400. (o) indicates an optional field.

MMS GSM SMS MMS-STATUS SMS-STATUS-REPORT Action type RP-Message-Type-Indicator Reply request Acknowledge should always be used MMS sequence number RP-Message-Reference Time Stamp TP-Service-center-time-stamp Information type — Action result TP-Status Command object — Sender address TP-Recipient address — TP-Discharge time Service type — Service subtype — Data content type — Message length —

The following table lists the fields of each service that should be mapped in the direction of PP to FP for MMS-STATUS-RPY interworking to GSM SMS. (o) indicated an optional field.

MMS GSM SMS GSM SMS MMS- RP-ACK RP-ERROR(SMS-SUBMIT- STATUS-RPY REPORT) Action type RP-Message-Type- RP or TP Message-Type- Indicator Indicator MMS RP-Message- RP-Message-Reference sequence Reference number Action result Value of RP-Cause or TP -Failure- “Successful” of Cause MMS is used

This chapter gives an example when the MMS transparent service is used for GSM SMS interworking i.e. the GSM SM-TP layer messages are conveyd accross the air interface with MMS protocol. In this case the MMS is only interworking with GSM SM-RP layer in the FP IWU as illustrated in FIG. 44.

Message Mappings Between MMS and SM-RP Layer

Item GSM Map No MMS MSG SM-RP MSG Ref. Status Note 1 MMS-SEND RP-DATA 9.3.2.1 M 2 MMS-SEND-RPY RP-ERROR 9.3.2.2 M 3 MMS-SEND-RPY RP-ACK 9.3.2.3 M 4 MMS-COMMAND RP-SMMA 9.3.2.4 M 5 MMS-COMMAND- RP-ERROR 9.3.2.5 M RPY 6 MMS-COMMAND- RP-ACK 9.3.2.6 M RPY

MMS-SEND and RP-DATA

Item GSM DECT No SM-RP MSG MMS MSG NWK MSG Coding RP-DATA MMS-SEND CC-INFO 1 RP-Message Action type Facility of type MMS — — <Action type> “MMS-SEND” 2 RP-Message MMS Facility or reference Sequence MMS number — — <MMS mapped from sequence nbr> RP-MR 3 — Message Facility or transmission MMS type — — <Transmission “Encapsulated” type> 4 — Content type Facility or MMS — — <Content type> “GSM SMS” 5 RP- Sender address Calling party Originator number address <Number <Number type> Mapped from type> RP-OA <Number plan <Number plan Mapped from id> id> RP-OA <CPN> <CPN> Mapped from RP-OA 6 RP- Receipient Called party Destination address number address <Number <Number type> Mapped from type> RP-OA <Number plan <Number plan Mapped from id> id> RP-OA <CPN> <CPN> Mapped from RP-OA 7 RP-User- User data IWU-TO-IWU data — — <User protocol “GSM SM-TP ID> message” — — <IWU-TO- SM-TP IWU info> message

MMS-SEND-RPY and RP-ERROR

GSM SM-RP MMS MSG DECT Item MSG MMS- NWK MSG No RP-ERROR SEND-RPY CC-INFO Coding 1 RP-Message Action Faclity of MMS Type type — — <Action type> “MMS- SEND- RPY” 2 RP-Message MMS Facility or MMS reference Sequence number — — <MMS sequence nbr> mapped from RP-MR 3 RP-Cause Action Facilty or MMS result — — <Action result> mapped from RP-MR 7 RP-User- Control IWU-TO-IWU data data — — <User protocol ID> “GSM SM-TP message” — — <IWU-TO-IWU info> SM-TP message

MMS-SEND-RPY and RP-ACK

GSM SM-RP MMS MSG DECT Item MSG MMS- NWK MSG No RP-ACK SEND-RPY CC-INFO Coding 1 RP-Message Action type Faclity of MMS Type — — <Action type> “MMS-SEND- RPY” 2 RP-Message MMS Facility or MMS reference Sequence number 3 — — <MMS mapped from sequence nbr> RP-MR — Action result Facilty or MMS — — <Action result> “Successful”

MMS-COMMAND and RP-SMMA

GSM SM-RP MMS MSG DECT NWK Item MSG MMS- MSG No RP-SMMA COMMAND CC-INFO Coding 1 RP-Message Action type Faclity of MMS type — — <Action type> “MMS- COMMAND” 2 RP-Message MMS Facility or MMS reference Sequence number — — <MMS mapped from sequence nbr> RP-MR 3 — Command Facilty or MMS type — — <Command “Memory type> available”

MMS-COMMAND-RPY and RP-ERROR

GSM MMS MSG SM-RP MMS- DECT Item MSG COMMAND- NWK MSG No RP-ERROR RPY CC-INFO Coding 1 RP-Message Action type Faclity of MMS Type — — <Action type> “MMS- COMMAND- RPY” 2 RP-Message MMS Facility or MMS reference Sequence number — — <MMS mapped from sequence nbr> RP-MR 3 RP-Cause Action Facilty or MMS result — — <Action result> mapped from RP-MR 4 RP-User Control IWU-TO-IWU data data — — <User protocol “GSM SM-TP ID> message” — — <IWU-TO-IWU SM-TP info> message

MMS-COMMAND-RPY and RP-ACK

GSM MMS MSG SM-RP MMS- DECT Item MSG COMMAND- NWK MSG No RP-ACK RPY CC-INFO Coding 1 RP-Message Action type Faclity of MMS Type — — <Action type> “MMS- COMMAND- RPY” 2 RP-Message MMS Facility or MMS reference Sequence number — — <MMS sequence mapped from nbr> RP-MR 3 — Action result Facilty or MMS — — <Action result> “Successful”

The call establishment of the service may either be linked to the SM-CP layer primitives, to the SM-RP upperlayer primitives or it can be the internal task of DECT system to decide the timing of the call setup and release.

In order to select the correct interworking unit and air interface profile in FP the following coding are used in the CC-SETUP message.

status Field within Standard Information in the information values within element GAP element the field/IE Normative action/comment <<Portable M Coded as in GAP identity>> <<Fixed M Coded as in GAP Identity>> <<Basic M service>> <Call class> x x x x “Messaging call setup” <Basic 1 1 1 1 “Other” The coding is service> defined by <<iwu attributes>> and <<call attributes>> <<Iwu- I attributes> > <Coding 0 1 “Profile specific coding” standard> <Profile ID> 0 0 0 1 1 “ E profile ” <NWK ID> 0 0 Ocete identifier <Network> 0 0 1 1 “GSM” <External 0 0 1 0 0 1 “GSM SMS” service type> 1 <HLC ID> 1 0 Octet identifier <HLC coding 0 0 0 0 1 “User protocol ID present” indicator> <User 1 0 0 1 0 “GSM Recommendation protocol ID> 03.40, SM-TP messages [xx]” <<call I attributes >> <Coding 0 0 DECT standard> Network layer 0 1 1 0 0 “DECT LRMS service attributes profile (E data profile” <<connection I attriubtes>> <<Number of 0 0 0 0 0 “No-U-plane” in E profile bearer case coding>>

An example of the usage of service negotation by using {CC-INFO} in DECT/GSM interworking will now be described.

1. PP Originated Call (See FIG. 45)

Upon receipt of CC-SETUP-ind with <<IWU-ATTRIBUTES>> containing the value “Connection exchange parameter negotiation” in the <<Negotiation indicator field>> from the CC entity the FP IWU will reject the request immediately issuing MNCC-REJECT-req with <<Release reason>> Hex 07 “Negotiation not supported” if the FP cannot support Extended exchange attributes negotiation.

If the FP can support the Extended exchange parameter negotiation the FP IWU will map the <<IWU-ATTRIBUTES >> information element contained in {CC-SETUP} message to the GSM <<BEARER CAPABILTY>> element of GSM {Setup} message.

1) Upon receipt of the GSM {Call proceeding} message the FP IWU will send DECT {CC-CALL-PROCEEDING} message to PP. If the {Call proceeding message} contained <<Bearer capabiliity>> information element the new values of the <<Bearer capability >> will be mapped into the <<IWU-ATTRIBUTES>> information element of the DECT <<CC-INFO >> message.

If no {Call proceeding} message is received or it does not contain <<BEARER CAPABILITY>> information element the service parameters have been accepted by the MSC IWF and no mapping between the <<BEARER CAPABILITY>> and <<IWU-ATTRIBUTES >> information element is needed.

2. PP Terminated Call (See FIG. 46)

Upon receipt of CC-SETUP-ind with <<IWU-ATTRIBUTES>> containing the value “Extended exchange parameter negotiation” in the <<Negotiation indicator field>> from the CC entity the PP IWU will reject the request immediately issuing MNCC-REJECT-req with <<Release reason>> Hex 07 “Negotiation not supported” if the PP cannot support Extended exchange attributes negotiation.

If the PP can support the Extended exchange parameter negotiation the PP IWU will add the new desired attributes values to the <<IWU-ATTRIBUTES>> information element of the {CC-INFO} message. The {CC-INFO} message can be sent only following by {CC-ALERTING} message.

2) and 3). It is then the responsibility of the FP IWU to suspend the submission of the {Call confirm} and {Alerting} message towards the GSM network until the new desired values have been received in the {CC-INFO} message. The new values in the <<IWU-ATTRIBUTES>> information element of the {CC-INFO} message are mapped into the GSM BEARER CAPABILTY element of {Call Confirmed} message. Other mappings between {CC-CONNECT} and {Connect} message as well as {CC-ALERTING} and {Alerting} messages are done as described in ETS 300 370 FINAL DRAFT prETS 300 370. Radio Equipment and Systems (RES); Digital European Cordless Telecommunications/Global System for Mobile communications (DECT/GSM) inter-working profile. Access and mapping (Protocol/procedure description for 3.1 kHz speech service). European Telecommunications Standards Institute. September 1994. 98 pages.

The PP IWU shall not send the {CC-INFO} message after {CC-ALTERTING} message if it agrees with the service parameters proposed in the {CC-SETUP} message. If {CC-CONNECT} message is received as a response to the {CC-SETUP} message the proposed parameters have been accepted. If the PP IWU accepts the parameters proposed by MSC the call establishment proceeds as defined in ETS 300 370.

The present invention includes any novel feature or combination of features disclosed herein either explicitly or any generalisation thereof irrespective of whether or not it relates to the claimed invention or mitigates any or all of the problems addressed.

In view of the foregoing description it will be evident to a person skilled in the art that various modifications may be made within the scope of the invention in particular the invention is applicable for use under other protocols including Wireless Customer Premises Equipment (WCPE) and Personal Handyphone System (PHS). 

What is claimed is:
 1. A messaging system for communicating a message between a first communications unit having a first messaging entity and a second communications unit having a second messaging entity, each messaging entity having a messaging call control means for establishing a messaging communications link with the other messaging entity; and a messaging means for, once the messaging communications link has been established, exchanging messaging information with the said other messaging entity wherein the messaging entity receives data from and transmits data to the application layer of the communication protocol such that each messaging entity comprises a virtual layer between an application layer and a network layer of a communication protocol.
 2. A messaging system as claimed in claim 1, wherein the messaging call control means operates under the control of the messaging means.
 3. A messaging system as claimed in claim 1, wherein the messaging information includes header data and user data associated with the message.
 4. A messaging system as claimed in claim 3, wherein the header data and the user data include data defining a message sequence number of the message.
 5. A messaging system, as claimed in claim 1, wherein the messaging communications link uses two links.
 6. A messaging system, as claimed in claim 5, wherein one of the links carries header data and the other link carries user data.
 7. A messaging system, as claimed in claim 6, wherein the said one link operates through a C-plane and the other link operates through a U-plane.
 8. A messaging system as claimed in claim 1, in the messaging communications link is made by means of a radio link between the first communications unit and the second communications unit.
 9. A messaging system as claimed in claim 8, wherein the first communications unit is a portable part and the second communications unit is a fixed part.
 10. A messaging system as claimed in claim 9, wherein the radio link operates according to the DECT WCPE or PHS protocols.
 11. A messaging method for communicating a message between a first communications unit and a second communications unit, the first communications unit having an application layer, a messaging entity and a network layer, the method comprising,the steps of: transmitting a signal from the application layer to the network layer as a means of establishing a call; exchanging messaging information between the application layer and the network layer by way of the messaging entity to communicate the message; and transmitting a signal from the application layer to the network layer as a means of disconnecting the call, wherein the messaging entity constitutes a virtual layer between the application layer and the network layer of the communication protocol.
 12. A messaging method for communicating a message between a first communications unit and a second communications unit, the first communications unit having an application layer, a messaging entity and a network layer, the method comprising the steps of: transmitting a signal from the messaging entity to the network layer as a means of establishing a call; exchanging messaging information between the application layer and the network layer by way of the messaging entity to communicate the message; and transmitting a signal from the messaging entity to the network layer as a means of disconnecting the call, wherein the messaging entity constitutes a virtual layer between the application layer and the network layer of the communication protocol. 